CN108592640A - For the electrode sealing in metallurgical furnace - Google Patents
For the electrode sealing in metallurgical furnace Download PDFInfo
- Publication number
- CN108592640A CN108592640A CN201810283685.3A CN201810283685A CN108592640A CN 108592640 A CN108592640 A CN 108592640A CN 201810283685 A CN201810283685 A CN 201810283685A CN 108592640 A CN108592640 A CN 108592640A
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- China
- Prior art keywords
- brick
- electrode
- flame retardant
- retardant coating
- stove
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Classifications
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- F—MECHANICAL ENGINEERING; LIGHTING; HEATING; WEAPONS; BLASTING
- F27—FURNACES; KILNS; OVENS; RETORTS
- F27D—DETAILS OR ACCESSORIES OF FURNACES, KILNS, OVENS, OR RETORTS, IN SO FAR AS THEY ARE OF KINDS OCCURRING IN MORE THAN ONE KIND OF FURNACE
- F27D1/00—Casings; Linings; Walls; Roofs
- F27D1/0003—Linings or walls
- F27D1/0023—Linings or walls comprising expansion joints or means to restrain expansion due to thermic flows
- F27D1/0026—Linings or walls comprising expansion joints or means to restrain expansion due to thermic flows the expansion joint being a resilient element, e.g. a metallic plate between two bricks
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- F—MECHANICAL ENGINEERING; LIGHTING; HEATING; WEAPONS; BLASTING
- F16—ENGINEERING ELEMENTS AND UNITS; GENERAL MEASURES FOR PRODUCING AND MAINTAINING EFFECTIVE FUNCTIONING OF MACHINES OR INSTALLATIONS; THERMAL INSULATION IN GENERAL
- F16J—PISTONS; CYLINDERS; SEALINGS
- F16J15/00—Sealings
- F16J15/002—Sealings comprising at least two sealings in succession
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- F—MECHANICAL ENGINEERING; LIGHTING; HEATING; WEAPONS; BLASTING
- F16—ENGINEERING ELEMENTS AND UNITS; GENERAL MEASURES FOR PRODUCING AND MAINTAINING EFFECTIVE FUNCTIONING OF MACHINES OR INSTALLATIONS; THERMAL INSULATION IN GENERAL
- F16J—PISTONS; CYLINDERS; SEALINGS
- F16J15/00—Sealings
- F16J15/02—Sealings between relatively-stationary surfaces
- F16J15/021—Sealings between relatively-stationary surfaces with elastic packing
- F16J15/028—Sealings between relatively-stationary surfaces with elastic packing the packing being mechanically expanded against the sealing surface
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- F—MECHANICAL ENGINEERING; LIGHTING; HEATING; WEAPONS; BLASTING
- F16—ENGINEERING ELEMENTS AND UNITS; GENERAL MEASURES FOR PRODUCING AND MAINTAINING EFFECTIVE FUNCTIONING OF MACHINES OR INSTALLATIONS; THERMAL INSULATION IN GENERAL
- F16J—PISTONS; CYLINDERS; SEALINGS
- F16J15/00—Sealings
- F16J15/02—Sealings between relatively-stationary surfaces
- F16J15/06—Sealings between relatively-stationary surfaces with solid packing compressed between sealing surfaces
- F16J15/067—Split packings
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- F—MECHANICAL ENGINEERING; LIGHTING; HEATING; WEAPONS; BLASTING
- F16—ENGINEERING ELEMENTS AND UNITS; GENERAL MEASURES FOR PRODUCING AND MAINTAINING EFFECTIVE FUNCTIONING OF MACHINES OR INSTALLATIONS; THERMAL INSULATION IN GENERAL
- F16J—PISTONS; CYLINDERS; SEALINGS
- F16J15/00—Sealings
- F16J15/16—Sealings between relatively-moving surfaces
- F16J15/40—Sealings between relatively-moving surfaces by means of fluid
- F16J15/43—Sealings between relatively-moving surfaces by means of fluid kept in sealing position by magnetic force
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- F—MECHANICAL ENGINEERING; LIGHTING; HEATING; WEAPONS; BLASTING
- F27—FURNACES; KILNS; OVENS; RETORTS
- F27B—FURNACES, KILNS, OVENS, OR RETORTS IN GENERAL; OPEN SINTERING OR LIKE APPARATUS
- F27B3/00—Hearth-type furnaces, e.g. of reverberatory type; Tank furnaces
- F27B3/08—Hearth-type furnaces, e.g. of reverberatory type; Tank furnaces heated electrically, with or without any other source of heat
- F27B3/085—Arc furnaces
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- F—MECHANICAL ENGINEERING; LIGHTING; HEATING; WEAPONS; BLASTING
- F27—FURNACES; KILNS; OVENS; RETORTS
- F27B—FURNACES, KILNS, OVENS, OR RETORTS IN GENERAL; OPEN SINTERING OR LIKE APPARATUS
- F27B3/00—Hearth-type furnaces, e.g. of reverberatory type; Tank furnaces
- F27B3/10—Details, accessories, or equipment peculiar to hearth-type furnaces
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- F—MECHANICAL ENGINEERING; LIGHTING; HEATING; WEAPONS; BLASTING
- F27—FURNACES; KILNS; OVENS; RETORTS
- F27B—FURNACES, KILNS, OVENS, OR RETORTS IN GENERAL; OPEN SINTERING OR LIKE APPARATUS
- F27B3/00—Hearth-type furnaces, e.g. of reverberatory type; Tank furnaces
- F27B3/10—Details, accessories, or equipment peculiar to hearth-type furnaces
- F27B3/12—Working chambers or casings; Supports therefor
- F27B3/14—Arrangements of linings
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- F—MECHANICAL ENGINEERING; LIGHTING; HEATING; WEAPONS; BLASTING
- F27—FURNACES; KILNS; OVENS; RETORTS
- F27B—FURNACES, KILNS, OVENS, OR RETORTS IN GENERAL; OPEN SINTERING OR LIKE APPARATUS
- F27B3/00—Hearth-type furnaces, e.g. of reverberatory type; Tank furnaces
- F27B3/10—Details, accessories, or equipment peculiar to hearth-type furnaces
- F27B3/12—Working chambers or casings; Supports therefor
- F27B3/16—Walls; Roofs
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- F—MECHANICAL ENGINEERING; LIGHTING; HEATING; WEAPONS; BLASTING
- F27—FURNACES; KILNS; OVENS; RETORTS
- F27B—FURNACES, KILNS, OVENS, OR RETORTS IN GENERAL; OPEN SINTERING OR LIKE APPARATUS
- F27B3/00—Hearth-type furnaces, e.g. of reverberatory type; Tank furnaces
- F27B3/10—Details, accessories, or equipment peculiar to hearth-type furnaces
- F27B3/20—Arrangements of heating devices
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- F—MECHANICAL ENGINEERING; LIGHTING; HEATING; WEAPONS; BLASTING
- F27—FURNACES; KILNS; OVENS; RETORTS
- F27D—DETAILS OR ACCESSORIES OF FURNACES, KILNS, OVENS, OR RETORTS, IN SO FAR AS THEY ARE OF KINDS OCCURRING IN MORE THAN ONE KIND OF FURNACE
- F27D1/00—Casings; Linings; Walls; Roofs
- F27D1/0003—Linings or walls
- F27D1/0006—Linings or walls formed from bricks or layers with a particular composition or specific characteristics
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- F—MECHANICAL ENGINEERING; LIGHTING; HEATING; WEAPONS; BLASTING
- F27—FURNACES; KILNS; OVENS; RETORTS
- F27D—DETAILS OR ACCESSORIES OF FURNACES, KILNS, OVENS, OR RETORTS, IN SO FAR AS THEY ARE OF KINDS OCCURRING IN MORE THAN ONE KIND OF FURNACE
- F27D1/00—Casings; Linings; Walls; Roofs
- F27D1/0003—Linings or walls
- F27D1/0023—Linings or walls comprising expansion joints or means to restrain expansion due to thermic flows
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- F—MECHANICAL ENGINEERING; LIGHTING; HEATING; WEAPONS; BLASTING
- F27—FURNACES; KILNS; OVENS; RETORTS
- F27D—DETAILS OR ACCESSORIES OF FURNACES, KILNS, OVENS, OR RETORTS, IN SO FAR AS THEY ARE OF KINDS OCCURRING IN MORE THAN ONE KIND OF FURNACE
- F27D1/00—Casings; Linings; Walls; Roofs
- F27D1/0043—Floors, hearths
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- F—MECHANICAL ENGINEERING; LIGHTING; HEATING; WEAPONS; BLASTING
- F27—FURNACES; KILNS; OVENS; RETORTS
- F27D—DETAILS OR ACCESSORIES OF FURNACES, KILNS, OVENS, OR RETORTS, IN SO FAR AS THEY ARE OF KINDS OCCURRING IN MORE THAN ONE KIND OF FURNACE
- F27D1/00—Casings; Linings; Walls; Roofs
- F27D1/04—Casings; Linings; Walls; Roofs characterised by the form, e.g. shape of the bricks or blocks used
- F27D1/045—Bricks for lining cylindrical bodies, e.g. skids, tubes
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- F—MECHANICAL ENGINEERING; LIGHTING; HEATING; WEAPONS; BLASTING
- F27—FURNACES; KILNS; OVENS; RETORTS
- F27D—DETAILS OR ACCESSORIES OF FURNACES, KILNS, OVENS, OR RETORTS, IN SO FAR AS THEY ARE OF KINDS OCCURRING IN MORE THAN ONE KIND OF FURNACE
- F27D1/00—Casings; Linings; Walls; Roofs
- F27D1/04—Casings; Linings; Walls; Roofs characterised by the form, e.g. shape of the bricks or blocks used
- F27D1/06—Composite bricks or blocks, e.g. panels, modules
- F27D1/08—Bricks or blocks with internal reinforcement or metal backing
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- F—MECHANICAL ENGINEERING; LIGHTING; HEATING; WEAPONS; BLASTING
- F27—FURNACES; KILNS; OVENS; RETORTS
- F27D—DETAILS OR ACCESSORIES OF FURNACES, KILNS, OVENS, OR RETORTS, IN SO FAR AS THEY ARE OF KINDS OCCURRING IN MORE THAN ONE KIND OF FURNACE
- F27D1/00—Casings; Linings; Walls; Roofs
- F27D1/14—Supports for linings
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- F—MECHANICAL ENGINEERING; LIGHTING; HEATING; WEAPONS; BLASTING
- F27—FURNACES; KILNS; OVENS; RETORTS
- F27D—DETAILS OR ACCESSORIES OF FURNACES, KILNS, OVENS, OR RETORTS, IN SO FAR AS THEY ARE OF KINDS OCCURRING IN MORE THAN ONE KIND OF FURNACE
- F27D1/00—Casings; Linings; Walls; Roofs
- F27D1/14—Supports for linings
- F27D1/145—Assembling elements
- F27D1/147—Assembling elements for bricks
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- F—MECHANICAL ENGINEERING; LIGHTING; HEATING; WEAPONS; BLASTING
- F27—FURNACES; KILNS; OVENS; RETORTS
- F27D—DETAILS OR ACCESSORIES OF FURNACES, KILNS, OVENS, OR RETORTS, IN SO FAR AS THEY ARE OF KINDS OCCURRING IN MORE THAN ONE KIND OF FURNACE
- F27D11/00—Arrangement of elements for electric heating in or on furnaces
- F27D11/08—Heating by electric discharge, e.g. arc discharge
- F27D11/10—Disposition of electrodes
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- F—MECHANICAL ENGINEERING; LIGHTING; HEATING; WEAPONS; BLASTING
- F27—FURNACES; KILNS; OVENS; RETORTS
- F27D—DETAILS OR ACCESSORIES OF FURNACES, KILNS, OVENS, OR RETORTS, IN SO FAR AS THEY ARE OF KINDS OCCURRING IN MORE THAN ONE KIND OF FURNACE
- F27D99/00—Subject matter not provided for in other groups of this subclass
- F27D99/0073—Seals
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- F—MECHANICAL ENGINEERING; LIGHTING; HEATING; WEAPONS; BLASTING
- F27—FURNACES; KILNS; OVENS; RETORTS
- F27B—FURNACES, KILNS, OVENS, OR RETORTS IN GENERAL; OPEN SINTERING OR LIKE APPARATUS
- F27B1/00—Shaft or like vertical or substantially vertical furnaces
- F27B1/10—Details, accessories, or equipment peculiar to furnaces of these types
- F27B1/12—Shells or casings; Supports therefor
- F27B1/14—Arrangements of linings
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- F—MECHANICAL ENGINEERING; LIGHTING; HEATING; WEAPONS; BLASTING
- F27—FURNACES; KILNS; OVENS; RETORTS
- F27D—DETAILS OR ACCESSORIES OF FURNACES, KILNS, OVENS, OR RETORTS, IN SO FAR AS THEY ARE OF KINDS OCCURRING IN MORE THAN ONE KIND OF FURNACE
- F27D1/00—Casings; Linings; Walls; Roofs
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- F—MECHANICAL ENGINEERING; LIGHTING; HEATING; WEAPONS; BLASTING
- F27—FURNACES; KILNS; OVENS; RETORTS
- F27D—DETAILS OR ACCESSORIES OF FURNACES, KILNS, OVENS, OR RETORTS, IN SO FAR AS THEY ARE OF KINDS OCCURRING IN MORE THAN ONE KIND OF FURNACE
- F27D99/00—Subject matter not provided for in other groups of this subclass
- F27D99/0001—Heating elements or systems
- F27D99/0006—Electric heating elements or system
- F27D2099/0021—Arc heating
Landscapes
- Engineering & Computer Science (AREA)
- General Engineering & Computer Science (AREA)
- Mechanical Engineering (AREA)
- Furnace Housings, Linings, Walls, And Ceilings (AREA)
- Vertical, Hearth, Or Arc Furnaces (AREA)
- Furnace Details (AREA)
- Discharge Heating (AREA)
- Carbon Steel Or Casting Steel Manufacturing (AREA)
Abstract
One metallurgical furnace has flame retardant coating, including an internal layer, contains the brick of the first kind, have certain thickness have dissipation hot function and the second class brick, to furnace chamber inside it is prominent, have the thickness of enough sacrifices.The stove further includes that a shell is divided into several sections, outer to be with force application part, for flame retardant coating inwardly to press from housing peripheral in flame retardant coating cooling meat.The force application part may include a stress part.The stove further includes a vertical compression component, and for applying a compressing force to flame retardant coating, flame retardant coating is pressed against in vertical direction when flame retardant coating is shunk.The stove further includes a cooling system, which includes an outer sleeve defendance shell and multiple air interchangers, and the air heats in outer sleeve are driven away hot gas with air interchanger.The stove may also include a bell, and bell has multiple suspension parts to pass through, this component in turn supports a network inside bell.Network supports the insulating materials wherein filled.The stove may also comprise an electrode sealing, and there are multiple diaphragm seals to press against electrode.
Description
It is on December 20th, 2013 that the application, which is the applying date, application No. is 201380078042.0, entitled metallurgical furnace
The divisional application of Chinese patent application.
Technical field
Present invention relates to a kind of metallurgical furnace, more particularly to a kind of metallurgical electric furnace.
Background technology
It is known in the art that having the metallurgical furnace of several forms, by flame retardant coating, round the outer steel shell of flame retardant coating, stove
Lid and cupola well are formed.The cross section of metallurgical furnace well known in the prior art can be rectangle, square or round
(in terms of surface or underface).Metallurgical furnace well known in the prior art, there are one metal structures for general tool, are supported by cupola well,
It is protected by flame retardant coating, for heating metal, clinker or other substances wherein.It is right over the metal and clinker of heating
One piece of region for being known as " headroom ", the spatially transverse surrounding also have flame retardant coating encirclement.Metallurgical electric furnace general electricity consumption is heated and is melted
Melt content.It is emphasized that general circle metallurgical electric furnace generates electric arc using three electrodes, to heat in cupola well
Substance.The flame retardant coating of typical metallurgical furnace is piled up by brick.
Fire brick layer is typically a thermal insulation layer, by part different in metallurgical furnace, including metal, clinker and hot gas, with
External environment isolation is come.In metallurgical furnace known in the prior art, melt temperature can be at 1400 degrees Celsius to 2200
Between degree Celsius.In use, the stove inner surface of fire brick layer may wrap the solidified slag or dust deposition of thickness reality
Object, the layer are also referred to as " skull ".Skull layer can be heated to 1000 degrees Celsius or more.The thickness of skull layer can be with electricity
The electric power height and arc length of stove and become, and arc length is the function of a voltage.
In some metallurgical furnaces known in the art, with the growth of usage time, due to thermal stress, flame retardant coating brick with
It will appear gap between brick, the inside of brick also will appear crack, especially after the cold cycling by repeating.Moreover,
Chemistry, heating power and mechanical stress flame retardant coating caused by the property of molten metal and clinker may be corroded or move back
Change, is finally disintegrated from inside.Fire resisting lamellar spacing and crack can cause molten metal to leak into flame retardant coating brick from furnace interior
In body.The loss and decomposition of brick may finally lead to metallurgical furnace failure.Gap between flame retardant coating brick body will increase object in stove
Across skull layer, through flame retardant coating and the risk that is eventually leaked into outside stove.
In some stoves known in the art, bell cannot play enough heat-blocking actions.Bell is likely difficult to conduct
One prevents the barrier that toxic gas leaks.The leakage of toxic gas such as carbon monoxide will cause potential danger to staff.
In some stoves known in the art, since high temperature caused by electrode may excessive heating furnace cover.In addition,
The high voltage to circulate in electrode makes the staff to work near bell face the danger to electrocute.
The present invention summarily solves the problems, such as some being present in metallurgical furnace well known in the prior art.
Invention content
The purpose of the content of present invention is in simplified form selectively introductory section concept.These concepts will be
To be further described in lower part specific implementation mode.The purpose of the content of present invention does not lie in the stated inventive technique of identification
Key feature or substantive characteristics are also not intended to determine the range of stated inventive technique.
In some embodiments, the present invention seeks to provide a kind of metallurgical furnace, which can be expanded using one,
And be points several sections of external box hat, surround a flame retardant coating so that flame retardant coating can expand receipts with the cold cycling of stove
Contracting.In some embodiments, the present invention seeks to provide a metallurgical furnace for carrying vertical compression component, the vertical compression portion
Part is in connection with flame retardant coating so that flame retardant coating can the dilation with the cold cycling of stove in vertical direction.At other
The present invention seeks to provide a metallurgical furnace with insulation bell in embodiment.In some further embodiments, this hair
The bright insulation for seeking electrode.In other embodiments, the present invention seeks to provide cooling outside stove.These various exemplaries are real
Applying can be used cooperatively, and will produce a synergy, therefore these embodiments are expected to set with other conventional metallurgical furnaces
Meter with the use of (such as:Conventional fire brick layer and/or electrode and/or external cooling system and/or bell are set
Meter).
First broad aspect first, the present invention provide a metallurgical furnace, and there are one flame retardant coatings for metallurgical furnace tool, surround
One furnace chamber, in stove heat for the heat that dissipates, which also has there are one force application part, for dividing flame retardant coating periphery
It is tightened to furnace chamber direction for several sections of shell when but flame retardant coating is shunk furnace cooling.
Force application part can allow flame retardant coating to expand in metallurgical stove heat, and apply when furnace cooling flame retardant coating is shunk
One compressing force.The appearance that force application part may surround sectionalized casing at least installs a wirerope, it is also possible to be used in outside
A plurality of wirerope, the surface for surrounding shell with interval are installed.Stress part can be mounted on these wireropes for adjusting wirerope
Length, to adjust the power of tension and wirerope application on stress part.
On the other hand, force application part can be multiple press members, be mounted on the peripheral surface of sectionalized casing, often
A press member presses in outer surface inwardly, to generate compressing force to shell.These press members can be spring portion
Part can be pressed in segmentation box hat outer surface with many side pressure component sides, can be by being applied to segmentation to adjust to increase or decrease
Compressing force on formula shell.
On the other hand, metallurgical furnace can be articulated in at least one stress part on force application part, be applied to adjust
Pulling force on force application part, thus generates compressing force.Stress part can be spring.Force application part can be by least one
Support member support, or by multiple support member supports.Supporting member can be mounted in the vertical of sectionalized casing periphery
Column, such as back up pillar.Positioning element allows sectionalized casing and force application part to have relative displacement.Force application part is at least with one
A positioning element engagement.Positioning element can be the wheel elements being linked at by axle center on supporting member.
On the other hand, the metallurgical furnace at least has there are one strength regulating member, is mounted on force application part, is used for
The strength of force application part originally is adjusted.At least one dynamometry component is connected to stress part.Dynamometry component can be a survey
Power meter, for measuring spring tension, for weighing the pulling force on stress part, to weigh the power that force application part is applied.
On the other hand, the cross section that the flame retardant coating can be on its longitudinal axis more at least is radially symmetrical,
Cross section that can be on its longitudinal axis more at least is in roughly circular.The shape of sectionalized casing is substantially in cylindrical,
It is in retracted configuration when metallurgical furnace cools down, and is in expansion form in metallurgical furnace heat temperature raising, laterally adjacent when is in expansion form
Housing segments between be likely to occur at least one gap.
On the other hand, the metallurgical furnace may there are one or multiple seal members, when for sealing metallurgical furnace heating
The gap occurred between the laterally adjacent segmentation of the shell of expansion form.These seal members can be some bands, be placed on resistance to
Fire bed is in place of the gap that between shell, occurs between the laterally adjacent segmentation of the shell of expansion form when heating up positioned at stove.
On the other hand, flame retardant coating innermost layer can be one layer of heat conduction brick, be placed in around furnace chamber for absorbing heat and dissipating
Heat.Flame retardant coating can also at least another layer of heat conduction brick, be placed on most interior heat conduction brick layer outer ring, further absorb heat and dissipate
Heat.The material of the additional brick layer can be different from the brick layer of innermost layer.The some of them of heat conduction brick can contain periclase.It is resistance to
Fire bed outermost layer can also be there are one one layer or multilayered thermally-conductive brick inside brick layer encirclement, and the brick material of this layer can be graphite.
On the other hand, in metallurgical furnace before original heating, at least one between innermost layer and secondary internal layer heat conduction brick
The interval insulant of layer, so that the diameter of flame retardant coating is more than housing diameter when retracted configuration.The interlayer barrier material can be
Certain material is made, and makes it that will burn or dissipate in stove heat, thus slot milling, as what is used for the expansion of heat conduction brick
Exceptional space.
On the other hand, the housing segments paragraph of metallurgical furnace can have at least three sections, can be according to the size of stove in proportion
Increase or reduce hop count, it is possibility to have eight sections or more.The edge being each segmented need by processing, make its with it is neighbouring
The edge energy harmony of segmentation.
On the other hand, metallurgical furnace can there are one or multiple seal members be placed in sectionalized casing and flame retardant coating
Between.Occur between the laterally adjacent segmentation of the shell of expansion form when each seal member seals the heating of one or more stove
Gap.
On the other hand, metallurgical furnace can there are one or multiple locking members as adjacent shells segmentation between work
Dynamic link.Each locking member determines the maximum value in gap between adjacent shells segmentation.
Second broad aspect, the present invention provides a kind of method that method reequips an existing metallurgical furnace, the metallurgy stoves
There are one surrounding furnace chamber, and in stove heat for outside the integral type of the flame retardant coating for the heat that dissipates and an encirclement flame retardant coating
Shell.This method can include multiple steps, and step includes that shell divide is surrounded fire resisting layer arrangement at least at sectionalized casing
When flame retardant coating is shunk when force application part cools down for furnace chamber, sectionalized casing is tightened to furnace chamber direction for one force application part.
On the other hand, force application part allows flame retardant coating to be expanded when furnace chamber heats, and can the fire resisting when furnace chamber cools down
Apply a compressing force when layer is shunk.Force application part may include a wirerope, be installed around sectionalized casing.
On the other hand, this method can use at least one layer of heat conduction brick that existing flame retardant coating is replaced to surround furnace chamber, and
Outside one or more layers internal brick layer is surrounded using at least one layer of brick.Internal layer brick material can be periclase, aluminium oxide, dioxy
SiClx or chrome brick, outer layer brick can include graphite brick.
On the other hand, this method may include a step, and at least one stress part is articulated to force application part.
Stress part can be spring, for maintaining the pulling force on force application part.
On the other hand, this method can include a step, and force application part is accepted at least one supporting member
On.Supporting member can be column, be mounted on the periphery of sectionalized casing.
On the other hand, this method may include a step, and force application part is installed at least one positioning element
On.Positioning element makes between sectionalized casing and force application part can there is certain relative displacement.Positioning element can be logical
Cross wheel elements of the axle center on plumb post.
On the other hand, this method may include a step, and at least one strength regulating member is connected to force section
On part, to adjust the power that force application part is applied.This method may further include one and be applied using the adjusting of strength regulating member
The step of power part length, to adjust the power of pulling force and wirerope application on stress part.This method can also include near
A few dynamometry component is connected on stress part, and measures the step of force application part is exerted a force.
On the other hand, force application part includes a wirerope and strength regulating member.Strength regulating member passes through adjusting
Wirerope length adjusts the pulling force on stress part, and adjusts the power that wirerope is applied.Dynamometry component can be dynamometer,
The power applied for measuring wirerope.
On the other hand, this method may include a step, place at least one layer of interval insulant in flame retardant coating same layer
Between heat conduction brick, the housing diameter when diameter of flame retardant coating will be caused to be more than retracted configuration in this way, interval insulant therein can be with
It is that certain material is made, makes it that will burn or dissipate in stove heat, thus slot milling, used as being expanded for heat conduction brick
Exceptional space.
On the other hand, this method may include a step by shell divide at least three sections, at least eight sections, and/or
Person is divided into more or less segmentations in proportion according to the relative size of stove.
On the other hand, this method may include a step, between sectionalized casing and flame retardant coating install one or
The multiple seal members of person.The shell of expansion form is laterally adjacent when each seal member seals the heating of one or more stove
The gap occurred between segmentation.
On the other hand, this method can include a step, be segmented using one or more pairs of adjacent shells are flexibly connected, from
And provide maximum gap between an adjacent shells segmentation.
The big aspect of third, the present invention provides a force application parts, and dissipate hot function when for having stove heat, and
The metallurgical furnace for surrounding the flame retardant coating of furnace chamber uses.Force application part is there are one structure is surrounded, for the segmentation around flame retardant coating surrounding
Formula shell, and have at least one stress part, for generating power on surrounding structure so that sectionalized casing is cold in furnace chamber
Tighten to furnace chamber direction when but.Stress part can be spring, and can with an initial tensile force adjuster, come adjust just
The power that force application part is applied when the beginning.
On the other hand, the use of initial tensile force component is to adjust the length of force application part.Force application part can mount
A upper strength regulating member.Strength regulating member can be dynamometer, the power applied for measuring force application part.
In terms of the 4th big, inventive technique provides for a metallurgical furnaces to design, which includes a fire resisting
Layer, furnace chamber and a vertical compression component.Flame retardant coating is made of multiple bricks, surrounds furnace chamber, in stove heat for dissipating
Heat.And vertical compression component applies compressing force to flame retardant coating, furnace cooling but when flame retardant coating shrink when from vertical direction press against fire resisting
Layer.Vertical compression component can be one or more spring.
On the other hand, vertical compression component can allow flame retardant coating to expand when furnace chamber is heated flame retardant coating expansion.
On the other hand, flame retardant coating can include one layer of brick around furnace chamber, and surround the second layer brick of this layer of brick.
On the other hand, stove can include one or more power transfering part, and the power of vertical compression component is transferred to
In one or more brick layer.Strength transfering part can be the coating member on a metastatic capacity to brick layer.
On the other hand, first layer brick can be not secured to second layer brick.
On the other hand, vertical compression component may include a strength regulating member, be used for strength of adjustment.Vertical pressure
Contracting component can be mounted on suspension parts, and suspension parts transfer to be connected to a supporting member.Suspension parts are with supporting member
Between connection can be flexible connection, so allow suspension parts activity, to allow the expansion and/or contraction of flame retardant coating.It is metallurgical
Stove can also include one or more length adjuster, convenient for adjusting the length of each suspension parts, thus adjust vertical pressure
The power that contracting component is applied.
On the other hand, flame retardant coating is configured to compensation when furnace chamber heats, and internal layer brick will be greater than the expansion of outer layer brick.
Flame retardant coating can including at least one layer of brick around furnace chamber and this layer of brick includes at least an outer edge thickness more than interior edge thickness
Brick so that when brick layer is heated by furnace chamber, expansion of the internal layer than outer layer brick bigger is compensated.
In the 5th broad aspect, the present invention provides a kind of method that method reequips an existing metallurgical furnace, the metallurgical furnaces
Include tool there are one surrounding furnace chamber, and the flame retardant coating in stove heat for the heat that dissipates, and includes selectively more
A brick layer around furnace chamber.This method includes a step, and vertical compression component is installed on flame retardant coating, is cooled down in stove resistance to
Flame retardant coating is compressed from vertical direction when fire bed is shunk, and vertical expansion is accommodated when stove heat flame retardant coating expands.Flame retardant coating can be with
Include the first layer brick around furnace chamber, and the second layer brick around the first layer brick.
On the other hand, this method may include install one or more power transfering part the step of, power transfer
Component is mounted between vertical compression component and flame retardant coating.Power transfering part can be a coating member, for shifting strength
Onto at least one layer in brick layer, the strength shifted is from the vertical compression component that can be a spring.
On the other hand, first layer brick can be not secured to second layer brick.
On the other hand, vertical compression component can include a strength adjuster for adjusting applied power.
On the other hand, which can include a step, and the installation of vertical compression component is articulated on suspension parts,
And suspension parts are then installed and are articulated on supporting member.
On the other hand, which may include a step, and suspension parts activity is articulated on supporting member, to
Allow expansion or contraction at least one of of the suspension parts activity to allow flame retardant coating.
On the other hand, which can include a step, one or more length adjustment is mounted on suspension parts
Device adjusts the power that vertical compression component is applied whereby to adjust the length of suspension parts.
On the other hand, which can include a step, and repacking metallurgical furnace is compensated when furnace chamber heats, flame retardant coating
Inner portion than its outer section bigger expansion.
On the other hand, which may include a step, and outer surface part ratio is leaned on using at least one in flame retardant coating
Close to the thicker brick of inner surface portion, when being heated by furnace chamber to compensate brick layer, expansion of the internal layer than outer layer bigger.
In the 6th broad aspect, the present invention provides a system for cooling down metallurgical furnace, which includes a housing
Cylinder and one or more air interchangers, the interior air heated by furnace chamber there is one layer of outer sleeve, and air interchanger is then used for
Hot gas around stove is driven away.
On the other hand, air interchanger can be used for by will be discharged from the hot-air around metallurgical furnace, will be relatively low
Warm air is pumped into outer sleeve.
On the other hand, colder air can be pumped into outer sleeve by one or more air interchanger.
On the other hand, the hot-air of surrounding can be extracted out by one or more air interchanger from stove.
On the other hand, outer sleeve can there are one or multiple gas vents, pass through for air.
On the other hand, which can contain one or more nozzle for spraying coolant liquid, from air layer to stove
It sprays the outer surface of shell.Nozzle can have there are one atomising device, coolant liquid is atomized, and mist is sprayed onto to the appearance of furnace shell
Face.
On the other hand, which can contain there are one monitor, the accumulation for monitoring coolant liquid.
On the other hand, the system can there are one modulators, for the accumulation situation according to coolant liquid, reduction cooling
The spray rate of liquid.
On the other hand, outer sleeve can be segmented by multistage and be formed.Each section can correspond to it is resistance to around metallurgical furnace
The segmentation of the box hat of fire bed, and every section of outer sleeve and its corresponding housing segments, hot-air folded therebetween is discharged.
In the 7th broad aspect, the present invention provides a kind of method of cooling metallurgical furnace.The method includes multiple steps, is used
Outer sleeve is surrounded the air being heated between metallurgical furnace and is discharged by one or more air interchanger.
On the other hand, which can spray to furnace shell surface there are one coolant liquid is sprayed inside air layer.
On the other hand, the method can there are one atomized liquid coolants, for the step of being sprayed onto stove outer surface.
On the other hand, which can include a step, and cooling liquid measure detected by stove rear surface is adjusted
Save the sprinkling of coolant liquid.
On the other hand, outer sleeve can be segmented by multistage and be formed.Each section can correspond to it is resistance to around metallurgical furnace
The segmentation of the box hat of fire bed, and every section of outer sleeve and its corresponding housing segments, hot-air folded therebetween is discharged.
In the 8th broad aspect, the present invention provides a bell for being used for metallurgical furnace, which includes a bell portion
Part, bell component have multiple suspension parts to be worn out from its appearance, support a network of bell components interior.It is interior
It is filled with insulating materials in portion's network, these materials can be castable, can also be electrical isolation and/or heat-insulating material,
Also/or can be the material not reacted with water.Insulating materials can be high alumina castable.The thickness of insulating materials is more than 40
Centimetre.
On the other hand, outer surface can form the copper cap-shaped structure in outside of one end open.
On the other hand, bell can order the bell component made by multiple measurements and tile.
On the other hand, the upper surface of bell is configured to that the coolant liquid being sprinkled upon thereon is allowed to flow to bell outward
Periphery, and cause that one layer of coolant liquid can be allowed to stay in thereon.Coolant liquid can be used for the cooling of bell and/or for bell
Fluid-tight prevents gas from being come out from the internal leakage of stove.
On the other hand, bell edge can include a continuous slot of one, for containing coolant liquid, to allow
One layer of flowing coating of cooling liquid with predetermined thickness is formed, is stayed in bell upper surface.The slot can have the outer wall higher than inner wall, from
And allow to be formed one layer of flowing coating of cooling liquid with predetermined thickness in bell upper surface.
On the other hand, bell can include a frame, be supported by suspension parts, which supports inner mesh
Structure.The frame can partly or completely be made by reinforcing bar, and inner mesh structure can part or be full steel grid.
On the other hand, bell can include a pump for spraying coolant liquid and/or coolant liquid being made to be passed to bell
On.
On the other hand, bell can include a takeup member, for being done between bell and the upper surface of metallurgical furnace
Sealing.
On the other hand, the gap in multiple bell components between adjacent bell component, at least one can use it is close
Seal agent sealing.Sealant can be cement, tar, high temperature silicone encapsulant or this several combination, for preventing liquid stream from passing through
Gap.
On the other hand, bell can include at least one opening to allow feed pipe.
On the other hand, bell can include a copper cylinder, and one end is stretched into inside furnace chamber, and the other end is projected into ratio
The high height of predetermined coolant liquid thickness, copper coin column surround feed pipe and are tightly connected therewith.
In terms of the 9th big, the present invention provides a kind of metallurgical furnace for smelting mineral, which includes one
Flame retardant coating, encirclement form furnace chamber, for the heat that dissipates when heating in stove.The flame retardant coating has an internal layer brick, has enforcement to dissipate hot
The thickness of function, the flame retardant coating contain the brick of the first kind, have certain thickness to have the brick of dissipation hot function and the second class, to
It is prominent inside furnace chamber, there is the thickness of enough sacrifices.The slag and gold that its thickness is formed when can be by using metallurgical furnace to smelt mineral
The characteristic of the predictable stabilization belonged to obtains.
On the other hand, be used for sacrifice thickness can with the difference of material property used on flame retardant coating different height,
Make corresponding change on flame retardant coating different height position.
On the other hand, the first brick and second of brick can be completely independent staggeredly bond on flame retardant coating, can also be
Substantially uniformity is interlocked bond on flame retardant coating, and the bond that can also uniformly interlock is in cellular.
In terms of the tenth big, the present invention provides a kind of method of modifying, reequips the existing metallurgical furnace for smelting mineral
Flame retardant coating.Flame retardant coating when the existing flame retardant coating is around furnace chamber, furnace chamber heating for the heat that dissipates.The method includes more
A step provides an internal layer of existing flame retardant coating, and there is this flame retardant coating the thickness for exercising dissipation hot function, the flame retardant coating to include
The brick of the first kind has certain thickness to have the brick of dissipation hot function and the second class, to furnace chamber inside it is prominent, have enough sacrifices
Thickness.
On the other hand, which includes one or more steps, according to formed slag when metallurgical furnace being used to smelt mineral
Predictable stabilization characteristic, determine for sacrifice brick thickness, and/or using metallurgical furnace smelt mineral when molten metal
Predictable stabilization characteristic, determine for sacrifice brick thickness.
On the other hand, which provides a step, and interlock bond the first and second of brick on flame retardant coating, and/or
Person is equably interlocked bond, and/or the bond that equably interlocks is in cellular.
In the 11st broad aspect, a kind of electrode sealing of present invention offer is used for metallurgical furnace.Stove includes a furnace chamber,
By the heated by electrodes for stretching into furnace chamber from opening, and electrode sealing includes at least three diaphragm seals, and two two sides of diaphragm seal are connected,
Each diaphragm seal has side pressure component, can be spring, can replace update, can also be used to adjust lateral pressure size, make
The face pressure for obtaining diaphragm seal on the electrode, both allows electrode longitudinally-moving in electrode seals, while can make between electrode and opening
Electrical isolation.
On the other hand, this at least three diaphragm seal is as an air seal, to prevent at least some gases from stove
Chamber leaks.
On the other hand, this at least three diaphragm seal allows electrode to make transverse movement in it, while preventing gas from letting out again
Leakage.
On the other hand, this at least three diaphragm seal allows electrode to make transverse movement in it, while playing electrical isolation again and making
With.
On the other hand, the electrode sealing can be comprising electrically insulating material around electrode, at least three sealings
On piece, which can be ceramic wool.
On the other hand, the electrode sealing may include a cavity around diaphragm seal, be filled with compression electrical isolation
Gas, as a pressurization, to prevent gas from being leaked from furnace chamber.
On the other hand, the electrode sealing can include the cooling-part of an electrical isolation, surround electrode.This is cold
But component may include a block casting plate, which can use wrapped with insulation, and insulating materials can be castable, such as high alumina
Castable.
On the other hand, cast panel can have one in the continuous pipeline of lining one, for guiding coolant liquid to flow wherein
It is logical.
On the other hand, the cooling-part may include one piece of copper coin.
On the other hand, the boundary face of the cavity at least part of can belong to cooling-part.
In the 12nd broad aspect, the present invention provides a kind of metallurgical furnace comprising a flame retardant coating is used for round furnace chamber
Dissipate heat when furnace chamber heats.The flame retardant coating has multiple this first brick for having the thickness for exercising dissipation hot function first, also
With multiple second bricks can sacrificing thicker than the first brick.Second of brick is to prominent inside furnace chamber.The stove further includes
One force application part, for when furnace chamber cools down, and flame retardant coating is shunk, the sectionalized casing of flame retardant coating periphery to be pressed to furnace chamber side
To.The force application part includes an encirclement structure, is used for around the sectionalized casing of flame retardant coating periphery and at least one
Tension member, will be outside the segmented of flame retardant coating periphery when furnace chamber cooling flame retardant coating is shunk for exerting oneself on surrounding structure
Shell presses to furnace chamber direction.The stove further includes a vertical compression component, for applying a compressing force to flame retardant coating, thus
When furnace chamber cooling flame retardant coating is shunk flame retardant coating is pressed against in vertical direction.The stove further includes a cooling system for using, the system
Include an outer sleeve and one or more air interchangers, outer sleeve surrounds one layer of air heated by furnace chamber, and changes
Device of air is then used to take away the hot gas around stove.The stove further includes a bell, which includes bell component, bell portion
Part has multiple suspension parts to be worn out from appearance, supports a network of bell components interior.Inner mesh structure
In be filled with insulating materials.
Description of the drawings
In conjunction with attached drawing and following detailed description, further feature of the invention and exemplary advantages will become it is aobvious and
It is clear to, wherein:
Fig. 1 is the exemplary horizontal sectional view of metallurgical furnace (electric furnace middle plane figure) of the present invention.
Figure 1A is a cross-sectional view partial schematic diagram (electric furnace lower flat figure), indicates that a metallurgical furnace of the invention shows
The lower part of the shell and associated components of example.
Fig. 2 is an exemplary longitdinal cross-section diagram of metallurgical furnace (electric furnace sectional view) of the invention.
Fig. 2A is an elevation (view immediately ahead of flame retardant coating), partly represents a metallurgical furnace example of the invention
Flame retardant coating inner surface.
Fig. 3 is longitdinal cross-section diagram (top detail view), partly draws out an exemplary fire resisting of metallurgical furnace of the present invention
The top of layer and vertical compression component, and partly depict one of metallurgical furnace of the present invention exemplary bell and one is shown
Plasticity cooling system.
Fig. 3 A are one piece of exemplary detailed views of single brick of the exemplary flame retardant coating of metallurgical furnace of the present invention.
Fig. 4 is an elevation (electric furnace elevation), partly represents a metallurgical furnace example and the part of the present invention
Ground depicts a cooling system example of metallurgical furnace of the present invention.
Fig. 4 A are a cross-sectional view (electric furnace detail views), indicate the present invention an exemplary flame retardant coating of metallurgical furnace and
Vertical compression component, and partly depict including one for the metallurgical furnace of the present invention including spraying coolant nozzle
Cooling system example.
Fig. 5 is a vertical view (electric stove tops vertical view), indicates an exemplary top of bell of this metallurgical furnace invention
Portion.
Fig. 6 is sectional view (the water cooled panels section of a part for an exemplary bell for indicating the invention of this metallurgical furnace
Figure).
Fig. 6 A are a plan view (water cooled panels ground plans), indicate an exemplary bell of this metallurgical furnace invention
The bottom of a part.
Fig. 7 is a longitdinal cross-section diagram (electrode sections figure), and an exemplary electrode for depicting the invention of this metallurgical furnace is close
Envelope.
Fig. 8 is a cross-sectional view (electrode middle plane figure), depicts an exemplary electrode of this metallurgical furnace invention
Sealing.
Fig. 9 is a cross-sectional view (electrode sink plan view), depicts an exemplary electrode of this metallurgical furnace invention
Sealing.
Specific implementation mode
Different embodiments is directed to the different aspect of stove design.It is to be appreciated that solve involved by existing design
At least some of disadvantage, and non-required various aspects for using all stoves discussed in this article designs.In some cases, originally
Single aspect described in text can independently solve at least some of known disadvantage.And exist between various exemplary implementation schemes
Synergistic effect, the implementation case will be expected to the design of other conventional ovens with the use of (for example, conventional brick matter fire resisting
Layer and/or electrode and/or external cooling system and/or bell design).
Brick matter flame retardant coating can be made of multiple laterally or longitudinally brick layer adjacent to each other.Each layer can with mutual linking,
To possess additional stability.In use, the heating of brick matter flame retardant coating can lead to the thermal expansion of brick.In order to compensate for this swollen
It is swollen, expansion paper can be placed between horizontally or vertically independent brick layer before using stove.Stove is once heated, the combustion of these paper
It burns, space is provided for the expansion in the level and longitudinal axis of brick layer.Between the outermost layer of brick and a steel shell, some
Stove can be furnished with one layer of expansion plate.The laminate have elasticity, be in order to allow brick outermost layer expansion after again will not excessively squeeze
On the inner surface of compressed steel shell, to reduce the stress suffered by fire brick layer.
When being exposed to the cold and hot period of a large amount of stoves, brick can show defect.For example, expansion paper all burnt, under
It is difficult to replace expansion paper before one thermal cycle therefore cold cycling often results in gap between brick, if plus the flowing of surrounding air, it will
Exacerbate the outflow of heat in stove, can also cause to leak out point molten metal from stove, penetrate into fire brick layer brick body.In addition,
Expansion and the period shunk may further result in friction and extruding between brick, and finally be lost and decompose brick, this can be final
Fire brick layer is caused to fail.In addition, commonly used in the service life of the expansion plate in space between the external box hat of filling and refractory brick
It is limited, as cycle will follow the string, so as to cause occurring gap between fire brick layer and shell.Between brick
Gap can further result in the unstable of fire brick layer, can finally aggravate the loss and decomposition of brick.Be currently known brick it
Between gap can also reduce the cooling efficiency of stove.
In some case study on implementation, each layer of brick relative to immediately last layer or next layer staggeredly overlap and chain.
Brick wall is bundled together by the structure that an external box hat defines, and all bricks are effectively locked together, and generates one initially
Firm structure.However, by a series of cold and hot period, brick can start to rupture and consume.For example, close to hot stove chamber
Interior brick can be heated more, and compared with those are far from the brick of hot stove chamber, they can expand more.When these bricks exist
When vertical direction expands, the linkage mode that they pile up can cause stress to the brick in expansion.This effect is grown in stove
Phase is idle, and it is rapid warmed up again in the case of, can more significantly.
When " skull " layer condensed in stove, partially due to the density variation of different melted materials and solid, in cooling
When rupturing to form crack, the integrality of brick becomes fragile.It has cracked when skull layer cools down and has been reheated rapidly in stove
In the case of, there is can will increase with property for " smuggling and tax evasion " in stove.Melted material will be leaked by skull when " smuggling and tax evasion ", then be led to
Fire resisting lamellar spacing is crossed, and is eventually flowed to outside stove.
The top of headroom in stove, metallurgical furnace usually have some form of bell.Bell can be propped up partly by stove itself
Support also entirely or partly can support (for example, accommodating the structure or building of the stove) by external means of support.In use,
Smog and dust can be deposited on the lower surface of bell, these deposits can have 10 to 20 centimetres of thickness.Below bell
Temperature can reach about 1200 to 1600 degrees Celsius in use.
Bell can be made with castable material, castable material both non-conductive or not heat conduction.In some instances, stove
The high alumina castable that can have is covered, maximum gauge is hung with steel anchor structure up to 10 to 20 centimetres and is fixed to water cooling steel plate
On.The purpose of bell is to provide the thermal insulation to ambient enviroment and/or provides a barrier, to prevent toxic gas, including one
Carbonoxide escapes into ambient enviroment, contributes to the environment that safety is created to staff.
Usually there are metallurgical electric furnace one or more electrodes to be suspended on above stove.The high temperature generated by electrode, can heating furnace
Region arround lid.In addition, the high voltage to circulate in electrode makes the staff to work near bell, cause to face electric shock
Lethal risk.
One cooling system can be provided, by water spray or in such a way that moisture film lands, water is sprinkled upon to the outer surface of stove.But
Security risk can be caused by being excessive water, especially in the case where molten metal is leaked from stove, for example, complete due to stove
Whole property fails (commonly referred to as " leaking out ").
Referring now to the drawings, wherein:Fig. 1 is a cross section of illustrative metallurgical furnace 10 implemented according to the invention
Figure or a top view.10 cross section of stove drawn in figure is round.Represented part is the headroom of stove.Headroom is stove
Parts more than 10 " slag lines ", do not had in usual operating process molten state or solid metal or slag in the part stove
It is interior.Refractory brick 20 in this segment space of stove 10 can with from stove 10 flue dust or dusty material be in direct contact, or and hot stove
Gas is in direct contact.Figure 1A illustrates a cross section, partly depicts 40 lower part of shell and shown in Fig. 1 exemplary
Metallurgical furnace associated components lower part.Stove 10 is to be surrounded by an outer sleeve 520, and supported by several structural columns 70.
Its structural column can be back up steel column.For outer sleeve 520, hereafter there is further description.
It reference is now concurrently made to shown in Fig. 1 to Fig. 4 A.With reference to Fig. 2, the stove 10 of drafting is made of following:Radially surround furnace chamber
30 flame retardant coating 20 and the shell 40 for radially surrounding flame retardant coating 20.Below furnace chamber 30, brick cupola well 45 can be by four layers of brick
It constitutes, brick material can be periclase brick (for example, internal layer one or more layers) and graphite brick (for example, outer layer one or more layers).It is swollen
Swollen paper or graphite carpet veneer (not shown) can be placed between these bricks.One iron structure, shape are the one of a sphere
A part for part intercept and the shell 40 is plotted in the bottom of figure, supports brick cupola well 45.Brick cupola well 45 contains
Metal melt, clinker or the other materials that is heated or will be heated in stove 10.
The stove 10 shown in Fig. 2 examples is by outer sleeve 520, several structural columns 70 of support stove 10 and covering stove 10
Bell 200 is constituted.There is trepanning on bell, there are the multiple electrodes 400 passed through, it is prominent from bell.Outer sleeve 520 will be
It is discussed further below.Exemplary bell 200 will be more fully described with reference to Fig. 6 and 6A.In Fig. 2 examples, electrode 400
It is radially surrounded by non-conducting encapsulation piece 415 and 410, this will be more specifically described in Fig. 7 to Fig. 9.Referring now still to Fig. 2,
The air interchanger 500 of middle description, the hot-air in the interlayer on 10 periphery of stove is extracted.With reference to Fig. 4 and Fig. 4 A, room temperature or cold sky
Gas will be by air admission hole 510, in the air blanketing of the outer sleeve 520 of entrance, to replace the hot-air extracted.According to this hair
Bright certain preferred embodiments, spray coolant device 540 can be used for spraying coolant liquid mist, such as water, to the outer of stove 10
Box hat 40, to cooling furnace 10.In Fig. 4 A examples, spray coolant device 540 is made of the array of hydraulic spray nozzle 545.Its
It configures and can be used in the case where not influencing final effect (for example, along there are one pillars 70 or multiple sprayers).It can
Spray coolant device 540 is arranged to spray fixed volume or the water of indefinite volume.It can be by spray coolant device 540
It is arranged to monitor the temperature of outer sleeve 520, and sprinkling volume and/or spraying time are adjusted according to temperature.Spray coolant fills
It can also includes water gauge (not shown) to set 540, when ponding for detecting, send alarm and/or close the system.
Spray coolant device 540 can also include a thermometer and a hygrometer (not shown) around outer sleeve 520
One or more specific position (not shown)s, the air themperature and humidity of monitoring, and fountain height and time are adjusted accordingly.
In preferred embodiment, during use, the temperature on 40 surface of shell and its surrounding air that are measured in outer sleeve 520
80 DEG C are must not exceed, air themperature can be lower than the temperature on 40 surface of shell, and maximum air humidity is reachable at 80 DEG C
100% or so.
In the example of Fig. 1, Fig. 2 and Fig. 4, the group of fire brick layer 20 radially surrounds furnace chamber 30 as an internal layer brick 22, the
Two layers of brick 24 are radially around internal layer brick 22, and outer layer brick 26 is again radially around the second layer brick 24.In other embodiments may be used
With one layer used, two layers, three layer or more layer brick.Brick layer number can become according to the material melted when being used in stove 10.
Each layer of refractory brick can have different thickness, such as successively increase thickness radially, this can be especially suitable for pre-
The case where phase flame retardant coating 20 in use can be by bigger pressure, or suitable for when solidification skull thermal coefficient compared with
Low situation.
In preferred embodiments, " skull " is locked on fire brick layer 20 for convenience, is located at periclase brick layer
The most interior brick layer 22 of 24 heating surface (i.e. inside), can be made of the different brick of thickness.It is different in further preferred scheme
The brick of thickness can interlock bond, to be formed such as in Fig. 2, inside honey comb like flame retardant coating shown in Fig. 2A and Fig. 4 A.In certain realities
It applies in example, such arrangement can be used by the inner surface of brick layer only in clinker area.
In use, for example possessing different thickness when starting with the metallurgical furnace as this kind of novel fire-resistant layer of flame retardant coating 20
The flame retardant coating of the most interior brick layer 22 (for example, honeycomb as shown in Figure 2 A) of the brick of degree can allow warm sludge and/or molten state gold
Belong to, and the dust in headroom and other materials, correspondingly adheres to or be solidified to the inner surface of flame retardant coating.Although flame retardant coating
Overall integrity and intensity be not damaged, but brick layer all inner surfaces with most thick brick 2200 in use can quilt
Chemically or mechanically corrosion or decomposition.Therefore, the penetrale of these most thick bricks 2200 is considered for " sacrificial
Domestic animal ".One layer of cast can be poured into a mould in order to reduce the corrosion that these brick surfaces can occur, when initial expects that all is in staggeredly
On bond or inner surface in cellular flame retardant coating, thickness may be about 50 millimeters, can be made of magnesium oxide.
In preferred embodiments, the brick that inside brick 22 and second layer brick 24 can be made from a material that be thermally conductive is constituted, from this
It absorbs heat in all molten metals, slag and hot stove gas in stove and the heat that dissipates.Other materials such as chrome brick refractory material is suitable for coloured
The smelting of metallic ore.Magnesium-graphite refractory is smelted suitable for ferrous metal ore.Based on silica and aluminium oxide
Refractory material is selected according to the property of contained material, is suitable for use of.In further preferred scheme, these flame retardant coatings
It can be made of magnesia or periclase material, for being smelted containing titanium ore (such as ilmenite).Outer layer brick 26 can be by graphite material structure
At.An advantage can be provided using one or more outer brick layer 26 with high heat conductance:For example, in melt substance from interior
Portion's flame retardant coating 22 and 24 leaks out, and can have similar temperature with outer steel shell 40 as outer layer brick 26, it can be advantageously
Keep the substance of leakage cooling rapidly and cure, prevents smuggling and tax evasion.In this case, outer brick layer 26 may serve as box hat
The equal heat of one of 40 extends, while but having the higher tolerance to heat fusing matter.
In preferred embodiments, outer brick layer 26 will include graphitiferous brick.Graphite brick thickness 150 to 300 millimeters it
Between, depend on the watt level of stove 10.For example, the size of graphite brick can be in 150 millimeters × 230 millimeters × 100 millimeters.Make
The physical size of brick can be determined by its weight, be convenient for transporting and using.It gives one example, the first layer of graphite brick
Using high 100 millimeters, 150 millimeters lateral long, radially-wide 230 millimeters of brick from bottom to top bond.These bricks can be vertical
Be staggered bond on direction, and directly bond without any expansion paper of folder or uses any type of cement on lower layer's brick.
Fig. 3 A show an exemplary brick 4000 of the exemplary flame retardant coating 20 in an illustrative examples.In order to mend
The difference that brick expands in vertical direction in radially single brick layer is repaid, in some embodiments, brick 4000 can be suitably
It is shaped into as shown in Figure 3A.Fig. 3 A have used three axis (x, y, z) to indicate.For convenience of example, heat source predictive role exists
On surface 4020 or plane y'-z'.Therefore, in use, the concave surface 4020 (inner surface) of brick 4000 is heated to be higher than convex surface or y-z
Plane.The height of the y-axis (y') of the inner surface 4020 of brick 4000 can be less than the height of outer surface (y), to compensate two faces
Between the difference that expands.In Fig. 3 A, the profile of the side 4080 of brick 4000 is an isosceles trapezoid, and x is equal to x'.This field skill
Art personnel will be understood that the profile in the face can also be that rectangle is trapezoidal or other kinds of trapezoidal (wherein x and x' are unequal),
As long as there is required difference high between y and y'.In this example, because the height difference on each piece of brick is to be so small, it is possible to
One only need to be made to a combination of every 4 to 5 bricks rationally to correct.Similarly, the inside face 4020 of brick 4000
(y'-z') length can be smaller than the expection arc length of exterior face (y-z).To a lesser extent, if depositing in vertical direction
Temperature gradient, 4000 inner surface of brick, 4020 following (z ") length can be less than the length in the top (z') of identical faces.
It should be understood readily by those skilled in this art, the shape of brick 4000 has to take into account its piling up property.It is true
Brick layer 22 and/or 26 has been protected while can be assembled from brick 4000, has changed the height and length of 4000 size of brick again, can demonstrate,prove
It is difficult in fact.In certain embodiments, one can only be chosen in multiple length, width and height for adjusting.Another solution
Exactly retain the flat hindfoot portion 4040 of brick, so that it is guaranteed that it has stable piling up property, and the then root of front section 4060
Shape as listed above is fashioned into according to heat distribution and different degrees of expansion.Also another solution is to allow difference
The brick of shape is distributed in brick layer 22,24 and/or 26, to provide stability.For example, the brick of different configuration can be paved with entire brick
Layer, but can also be changed according to the position that brick 4000 is piled up.The configuration of different bricks can also be only applied to certain stacking bricks,
And other places are not applied to.For example, on the brick that the normal brick of surrounding surrounds, or with serial brick on the diagonal
It is upper, etc..
For example, for internal high 11 meters of brick wall, using high 4 inches or 101.6 millimeters at normal temperatures of brick,
Brick inner surface 4020 is by 800 degree Celsius of bearing temperature, 400 degrees Celsius of hull-skin temperature.The correction needs of its brick shape are accomplished
Every four layers of brick is about 3 millimeters (i.e. brick outer surface is 3 millimeters higher than inner face).It is every in vertical direction also, in addition to the brick of eight layers of top
4th layer of brick makees so correction.Technical staff artisan will readily appreciate that on radial One-Story Brick, making suitable correction, hang down to compensate
Histogram non-uniform thermal expansion upwards.
Mode bond identical with outer brick layer 26 may be used in interior brick layer 22 and the second brick layer 24.In these examples, three
A layer 22,24 and 26 is independent of each other in vertical direction.
In preferred embodiments, the brick of flame retardant coating 20 is after shaping so that each layer of flame retardant coating 20 shape after putting
At a series of circular layers, one layer round one layer.Two sides of brick ream certain angle, and lead and trail edge is also cut into properly
Shape so that when there is sufficient amount of brick to be placed adjacent, side then side when, form a circle.The circle can thus be fought
The pressure of any level.
In the stove 10 shown in Fig. 1 and 2, flame retardant coating 20 is mounted in shell 40.40 shape of shell can be cylinder, and
And it can be formed from steel.Technical staff knows that other metals or material are also suitable the material as shell 40.In drawn example
In, shell 40 is divided into several segmentations 42, is divided by the gap between vertical incision 44 or adjacent sectional 42.It is shown in Fig. 1
Embodiment in, shell 40 is divided into eight paragraphs 42.Under normal circumstances, the quantity for increasing shell segmentation 42, expands increasing
With the distributing homogeneity for being applied to pressure on flame retardant coating 20 during contraction.More shell is segmented 42 quantity, is suitable for whole
The relatively large sized situation of body stove, and less segmentation can then be suitble to relatively small smelting furnace.In preferred embodiment
In, in the bottom end that the Shell Plate is each segmented, all weld upper steel or there is the Circular Plate of same material with shell, as one
A wheel rim 46.It can be punched on wheel rim 46, by shell carriage bolt on the wheel rim of the cupola well 47 of lower part, as shown in Figure 4 A.
In this example, 60 to 70 millimeters of gap can be needed between each shell paragraph 42.In example shown in figure 1A, often
The both sides of a shell paragraph 42, a band of all burn-oning is as wheel rim 43.Eyelet is equipped on wheel rim, be using long screw 41,
One shell paragraph is bolted on the wheel rim of adjacent paragraph.After screw is fixed so that there are 60-70 millimeters of gaps to deposit between paragraph
.The number of screw 41 can be adjusted correspondingly, to bear the ferrostatic pressure in operating process in stove 10, to lock
Determine the maximum swelling position of shell 42.Can be that steel or other materials are made by some in order to avoid furnace gases are by the clearance leakage
At slice band, be placed on behind outer brick layer 26, resist shell paragraph 42, cover the gap.The width of band can compare gap
It is slightly larger, become a sealing between two adjacent shells paragraphs 42.In other embodiments, it is elastic can to add energy for wheel rim 43
Material make the sealing be formed as between two adjacent shells paragraphs.Technical staff will readily understand that other suitable sealings fill
The leakproof hermetic seal between being used as adjacent shells paragraph 42 is set, to during 20 dilation of flame retardant coating and corresponding
When adjacent shells segmentation 42 moves away from each other, prevent gas from leaking or entering.In preferred embodiments, the institute of coverboard
After having segmentation paragraph all fixed and installing, brick layer 26,24 and 22 can nestle up coverboard bond.When stove 10 prepares
It finishes when beginning to use, being fixed on the screw of bottom rim 46 can all back out, and coverboard with expansion and can be shunk freely
Activity.One or more force application parts will be laterally set around shell paragraph 42, force application part is by binding component 50 and draws
Power component 60 forms.
In preferred embodiments, the binding component 50 can be cable wire, and cable wire can be braiding cable wire, by crowd
More steel wires or steel line are weaved into.Technical staff will readily understand that the binding component 50 of many other forms can also close
It is suitable.Binding component 50 is tightened up, and applies a pressure on housing segments 42, this pressure is passed to fire resisting by housing segments 42 again
On layer 20.
The possibility that power can be more than maximum collapse ability is bound in normal operation condition in order to reduce, locking member 41,
It can be screw, can fix the position of the shell paragraph 42.When shell paragraph 42 is expanded into latched position, further
Expansion binding component will be made to be damaged, internal ferrostatic pressure can be supported by the shell paragraph 42 locked, without leaning on pulling force
Component is not also by binding component.
In preferred embodiments, binding component 50 is maintained by the stress part 60 on binding component 50
Tightening state.In certain preferred aspects, stress part 60 is heavy-duty spring.
In some embodiments, the force application part includes multiple press members, is arranged in the outer of sectionalized casing 40
Surface, each equal outward surface pressure of press member, to generate pressure to shell.These press members can be spring, directly
Connect and be pressed in box hat paragraph outer surface, or can be compressed tablet, directly press against outer surface, or can side pressure on the outer surface, example
Such as, using spring (not shown).In some embodiments, press member can be adjusted, and increases or decreases and is applied to segmentation
Pressure on formula shell 40.In some embodiments, press member can be propped up by the support construction except metallurgical furnace 10
Support, such as use the laterally connected back up steel column 70 around metallurgical furnace 10.Technical staff is in view of such as 10 size of stove
Specification and expecting pressure etc. will be easily the support construction of press member, determine number, form and configuration appropriate.
In the embodiment painted in fig 1 and 2, binding component 50 is supported by multiple columns 70.In the embodiment painted
In, column 70 is four back up pillars, and radially uniform distribution places one, around shell 40 every an angle of 90 degrees.Technology people
Member will readily understand that, under without departing from the teachings of the present invention, can use more or less pillar 70.If using when pulling force portion
The maximum pull ability that part 60 provides is not big enough, then it may be desirable to use multiple binding components 50 and stress parts 60, and can
To adjust the quantity of column 70 and stress part 60, to meet the needs of to always binding power, especially 10 lower metal area of stove
The demand in domain.With reference to Fig. 4, in a preferred embodiment of the invention, four pairs of cable wires serve as binding component 50, along the height of stove 10
Degree positioning, per the positioning of a pair of cable wire so that two stress parts 60 of this pair of binding component 50 are opposite to each other in diameter
Both ends.Use multipair wirerope and a option, it is therefore intended that reduce the possibility of binding system failure.Equally, Yi Duigang
Two probability to break down simultaneously in cable are very low.In addition, being once suitably determined that the size of binding system is big
It is small, use a plurality of wirerope to provide one so that binding system is convenient for the illustrative advantage safeguarded.Because a component occurs
When failure, other component can have enough intensity, independently to play a role.Therefore, if a stress part 60 or tied up
Determine component 50 to need replacing or repair, the pulling force portion for needing to change or repairing can be dismantled in the case where not dismantling other component
Part 60 or binding component 50, therefore generally speaking, the work of horizontal binding system will not influenced by safeguarding.In addition, having above-mentioned
The maintenance of locking system, binding component 50 and stress part 60 can become to be more prone to.
With reference to figure 1 and Fig. 2, in preferred embodiments, binding component by cable wire 50 as an example, by positioning element
52 support and position, and positioning element can be installed to back up column 70 by wheel component and be formed.These positioning elements 52 allow
Make expected relative motion between cable wire 50 and shell paragraph 42.
In certain preferred aspects, the pulling force on stress part 60 is measured using a machine journey or device, it can
To be conducive to the target pulling force on the binding component 50 for monitoring and maintaining.In preferred embodiments, which can be one
A calibration gauge for measuring spring elongation, spring elongation are multiplied by the spring constant of the stress part 60 equal to the pulling force on component.
The adjusting of pulling force can be thread by using length adjuster 90, example used, carry out adjustment length, to adjust binding
The pulling force of component 50.The result that binding component 50 tenses is exactly to generate a pressure to act on shell 40, and also generate one
Pressure acts on flame retardant coating 20.It draws tightlier the pressure of bigger will to be caused to act on flame retardant coating 20.In preferred embodiment
In, with to maintain the material that contains melt substance or will heat, the required pressure i.e. spring of stablizing in the lower part of stove 10 is drawn
Power is compared, and suitable for maintaining, 20 radial direction of flame retardant coating stablizes required pressure around headroom and pulling force wants relatively low.When molten iron static pressure
For power when the lower part of the smelting furnace containing molten metal increases, if binding power is not as pressure increases, the lower part of shell paragraph 42 can
To protrude outward and cause the inclination of entire paragraph.Therefore a level meter can be placed in bottom rim, whether determines wheel rim
At or approximately at level.Lower part pulling force is increased by the length of the binding component 50 of shortening again, and then tightens shell paragraph
42, to keep the wheel rim to be in an approximate horizontal position.
In stove in use, flame retardant coating 20 is heated and form a temperature gradient, about 1000 degrees Celsius on inner surface, arrive
Its outer surface is reduced to about 80 degrees Celsius.20 one way or another of flame retardant coating expands when heated.In preferred embodiments,
Internal layer 22 and 24 periclase block layer of the second layer can absorb and expand dissipation heat, be corresponded at a temperature of being expanded into each piece of brick
Dilation dimension.For example, brick that is close or being in direct contact with molten metal, clinker, or in furnace chamber it is direct with hot stove gas
The brick of contact can be warmmer therefore also swollen compared with not being in direct contact with molten metal or clinker or furnace gases
Swollen is more severe.It is to be noted that in use, some bricks in 22 lower part of interior brick layer can wrap up last layer
The slag or metal or solid " skull " of " solidification ", fusing point is up between 1000 degrees Celsius to 1600 degrees Celsius.Pass through holding
In certain target temperature range, skull can be in solid-state always and can be as a liner of stove 10 flame retardant coating 20, can be with
Additional stability is provided for stove 10, and can play prevents molten metal or clinker from leaking into 20 brick body of flame retardant coating
Effect.By taking typical ilmenite metallurgical furnace as an example, clinker is about 1640 DEG C containing 80% TiO2 its liquid phase setting temperature is had more than,
It will be solidified when molten slag touches 800 to 1000 DEG C of flame retardant coating 20.Solidification clinker prevents molten as one " shell "
Further attack of the slag to flame retardant coating 20.Rule of thumb, today it is not possible to which melting high oxidation titanium clinker can be resisted by finding out one
The known oxide material of corrosion, only refractory metal, such as molybdenum, tantalum and platinum.As soon as the importance of smelting titanic iron ore,
It is to control and maintain this solidified slag thickness of the shell at about 300 millimeters, as a security target.
In the preferred embodiment of the invention, for flame retardant coating 20 initially equipped with expansion paper (not shown), thickness is about 0.4 milli
Rice, is placed between two bricks of same radial brick layer.The calculating of paper sheet thickness used is according to the desired brick of compensation
Expansion needs to carry out.Therefore, the overall diameter of stove 10 will be close to expansion form expected from stove 10 including expansion paper
When overall diameter.Once being heated when in use, expansion paper will burn, and leaving space is expanded to fire brick layer 20, fills up this
Space.In preferred embodiments, in the outer brick layer 26 being made of graphite brick, graphite felt can be used to replace expansion paper.
For the first time in use, (expanded form can also be referred to as in the text when 20 brick lateral expansion of flame retardant coating
"horizontal" or " radial direction " expansion), by the expansion paper burning referred to above, the overall diameter of flame retardant coating 20 should be retained in one
The diameter when expansion of a constant or heating configuration.But when stove 10 cools down, flame retardant coating 20 is and resistance to by cooling meat
Fire bed 20 will be contracted to contracted configuration, and diameter reduces.
In a preferred embodiment, outer steel shell 40 will have the diameter consistent with the contracted configuration of flame retardant coating 20 first, should
Diameter is known as first diameter.Box hat 40 can substantially make cylindrical shell, and size is first diameter, then with a series of vertical
It cuts, forms at least three a set of or at least eight a set of shell paragraphs 42 with longitudinal incision 44.
When flame retardant coating 20, including expansion paper, when such as above-mentioned installing, flame retardant coating 20 can have corresponding to expansion
Diameter when configuration.As discussed above, box hat 40 can be segmented 42 by a set of arc shell and form, they are assembled shape
The cylinder of diameter when at collapsed configuration corresponding to flame retardant coating 20.Therefore, it has been installed when steel shell paragraph 42 surrounds
Flame retardant coating 20 assemble when, can have gap or vacancy between adjacent shell paragraph 42.
When stove 10 is cold, such as during maintenance or period is not used, the brick of composition flame retardant coating 20, which is cold, is in
Contraction state.Shell paragraph 42 can substantially be pressed to the middle longitudinal axis of stove 10 by the pressure being applied on box hat 40 simultaneously, and when whole
When a stove is cooled to room temperature, gap or vacancy between adjacent segment paragraph 42 will reduce or disappear.In preferred embodiment
In, the brick in contraction equally can be pressed to 10 center of stove by compressing force, to reduce the formation in gap or vacancy between brick.
When flame retardant coating 20 enters retracted configuration, the tense situation of binding component 50 will reduce or loosen.When beyond its automatic adjustment
Can be a thread with length adjuster 90, to shorten the length of binding component 50, to keep identical when range
Power is bound, when to allow the brick of flame retardant coating 20 to be finally heated again, can be expanded towards each other.When beyond its automatic adjustment
When range, through the length of adjustment binding component 50, to deal with corresponding expansion.
When stove 10 heats again, flame retardant coating 20 will heat up, and be expanded into expanded configuration, have the diameter of opposite bigger.With
It flame retardant coating 20 to expand, between the adjacent paragraph 42 of shell 40, it may appear that vacancy or gap, and it is the expansion for compensating shell 40,
Stress part 60 (such as spring) is opened and expands, and binding component 50 (such as cable wire) therewith can move.When expansion,
Wirerope can lead to the rolling of positioning element 52 relative to the movement of shell paragraph 42.Positioning element 52 is by rolling to allow
Movement is stated, while reducing the frictionally damage of the binding component 50 to can be used thread 90 to increase.
In preferred embodiments, flame retardant coating 20 and shell 40 press against the brick layer 48 and 49 of cupola well flame retardant coating 45.At these
In embodiment, expansion paper can be placed in during installing stove between brick layer 48 and 49, before just using stove, in brick layer 48
And reserved space between 49.
The process of the heating and cooling of stove and expansion and the contraction of resulting flame retardant coating 20, can be repeatedly formed perhaps
Multicycle.Binding component 50 keeps nervous and applies compressing force in the process, to reduce the gap formed during week, and increases
The stability of 20 brick of flame retardant coating when adding cold cycling.In addition, between blocks are actually can be with reserved space, such as by using swollen
The mode of swollen paper, to reduce the thermal stress generated due to initial bubble when stove starts.
Referring specifically to Fig. 2 and Fig. 3, some exemplary implementations according to the present invention, preferred metallurgical furnace 10 includes a kind of machine
System, for compensating flame retardant coating 20 during heated and cooling, the vertical expansion of generation and contraction.
In Fig. 3, in preferred embodiments, multiple coating members 104 each have different diameters, right
It should be placed on flame retardant coating 20 in flame retardant coating brick layer 22,24 and 26.The stove made according to the present invention can square, square
The shape of shape, hexagon, the linear section of octagonal or other cross sections.In these examples, coating member 104 is made suitably
Shape (square, rectangle or other shapes), and be circular for stove cross section, coating member 104 can be round.
In preferred embodiments, the outer diameter and internal diameter that each coating member 104 has are roughly the same with corresponding brick layer.
In other embodiments, for example, outer diameter be less than corresponding brick layer coating member 104 and/or internal diameter again smaller than corresponding brick layer,
It can also use.In preferred embodiments, coating member 104 is made of a continuous central portion of one, but skill
Art personnel are it will be readily understood that coating member 104 can also be made of multiple independent parts or the ring separated.In coating member
Between 104 and flame retardant coating 20, a thin layer of elastic material can be placed, if Teflon (not shown) is as sealing, to prevent from appointing
What leaks through the gas of flame retardant coating.Similar material can be also placed between flame retardant coating 22 and 24, between flame retardant coating 24 and 26, in dome brick
On, to improve leakproofness.
In preferred embodiments, multiple press members 100 are arranged on the circumference of each coating member 104.Into
In the embodiment of one step, coating member 104 is not needed, press member 100 is directly contacted with flame retardant coating upper surface.Other
In embodiment, coating member 104 can be made of multiple paragraphs or multiple individual plates can be placed on single brick or brick row
On.In further embodiment, can arrange single a coating member or other component radial multiple brick layer it
On.
Press member 100 is designed to apply downward pressure or power to flame retardant coating 20.In use, flame retardant coating 20 is heated
When caused brick thermal expansion flame retardant coating 20 will be caused to be expanded to expanded configuration.As discussed above, this will be a kind of towards each
The expansion in a direction, including vertical direction.Therefore, the whole height of each layer 22,24,26 of flame retardant coating 20 can be with stove 10
Cold and hot period and brick heated and cooling and change.Also as discussed hereinbefore, interior brick layer 22 will be exposed to higher temperature
In, therefore will expand more than the second layer 24, and so on.So the interior brick layer 22 in expanded configuration, unless otherwise
Preset height, it is contemplated that more slightly higher than the second layer 24 or outer layer 26.
In preferred embodiments, press member 100 is steel spring, is built on the surface of each coating member 104
In the hat shape part 102 being equipped with.In a further preferred embodiment, press member 100 surrounds each radially evenly
The circle distribution of covering 104.
In the embodiment shown in fig. 3, press member 100 mounts a pressure regulator 110, and the latter transfers to mount
A suspension parts 120, suspension parts 120 can be rigid.In preferred embodiments, pressure regulator 110 can
To be a length adjuster, and the rigid suspended component 120 can be a steel pole.In further preferred embodiment party
In case, the pressure regulator 110 and rigid suspended component 120 can make from a single steel pole, and steel pole incision makes again
It is threadedly coupled and connects so that the rigid suspended component 120 and pressure regulator 110 pattern length can be adjusted.
By adjusting the pattern length of rigid suspended component 120 and pressure regulator 110, acts on the downward power of flame retardant coating 20 and also obtain
To adjust and therefore can be maintained on a target level.
In use, flame retardant coating 20 is heated and cooling, thus longitudinal dilatation and when shrinking, press member 100 as compensation and
It shrinks and expands, always press against flame retardant coating 20 downward, in order that increasing the longitudinal stability of flame retardant coating 20.This mode is expected
The vacancy and out-of-flatness formed between vertical brick layer can be minimized.It particularly points out, is mutual for for example longitudinal each layer
Independent flame retardant coating, interlayer do not have the case where any cement or other binders, can by the increased longitudinal stability of system institute
To improve the overall stability of the structure, and the service life of stove 10 can be increased.
In the embodiment shown in fig. 3, rigid suspended component 120 is lived by sliding laterally component or pulley part 140
It is dynamic to be articulated to horizontal support elements or crossbeam 130.In use, the radial lateral expansion of flame retardant coating 20 or when shrinking, rigidity
Suspension parts 120 can also move certain corresponding distance.It does so, the direction that press member 100 is exerted a force can be with fire resisting
Each layer of center of gravity of layer 20 is consistent.The way can limit or eliminate flame retardant coating occur can cause tilt and collapse can
It can property.In preferred embodiments, endless member 104 if yes will be divided into several sections, to allow flame retardant coating
20 bulk expansion and contraction.
In certain embodiments of the invention, existing radial symmetric or " circle " metallurgical furnace can bring repacking or " change
It makes ".In a preferred method, box hat outside the cylinder of ready-made stove is cut into several such as three, eight or the shell segments more than eight
It falls.
In a preferred method, it is arranged in around the box hat cut to one or more binding component levels.These bindings
Component, which is tightened up, to be loaded onto, and keeps tightening by the stress part being loaded with, stress part can be heavy-duty spring.Preferred real
It applies in scheme, binding component is cable wire, and is arranged on sectionalized casing, is in one or more pairs of distributions along its short transverse.
Binding component under tension applies a compression or inside then on the flame retardant coating of the incision shell lining of transformation stove
Power.
In heating and cooling, the flame retardant coating of stove, which is transformed, can expand and shrink, and steel shell paragraph will be with the flame retardant coating
Expansion and contraction, inwardly or outwardly move, by binding component by the elongation and contraction of stress part, to make its holding
It is in place.By carrying upper length regulator and tension measurement device to binding component, you can with holding, adjustment and/or monitoring
Bind the tension on component.
The preferred method for reequiping or improving existing stove further includes that a step replaces flame retardant coating.Fire resisting after replacement
Layer can be made of an interior brick layer, the second brick layer and outer brick layer, and the cross section of each layer is radially symmetrical.Internal layer and the second layer
Using the hot refractory material such as periclase that dissipates, the outer layer close to shell is then using the material with high heat conductance, such as graphite.
In preferred embodiment, brick bond, longitudinal brick layer will staggeredly will be mutually independent longitudinal.
In a preferred method, can be by wheel rim before stove startup, such as with welding, it is connected to one or more arc
The bottom end of shell paragraph.Shell segmentation can be fixed on the wheel rim of bottom cupola well with bolt.After the completion of brick layer is filled and is built, spiral shell
Bolt is unloaded from transformation stove, to allow shell paragraph to make the movement relative to flame retardant coating.
In preferred embodiments, between can expansion paper being placed in radial brick, it is similar to be in form one
The diameter of the flame retardant coating of expanded configuration.Once stove is using heating, these paper will burn, and the brick of prolonged expansion will be filled up
Resulting vacancy.
In further preferred embodiment, be transformed or improve existing radial symmetric stove or cross section be square or
The step of method of square furnace, includes installation longitudinal compression system, longitudinal stability for improving flame retardant coating.Longitudinal pressure
The installation of compression system may include that one or more press members are arranged on flame retardant coating, to flame retardant coating application downward pressure.It is preferred that
Method may include that press member is arranged on coating member or other component on flame retardant coating radially each brick layer.According to covering
Cover can respectively use a coating member in every layer in the two, three or more layer of longitudinal brick layer.Press member
On the surface that can mount or be welded on coating member or other component, and it can be built in a hat shape part.Rigidity
Suspension parts, it can be steel pole, can be articulated on press member, and press member can be spring.Preferably implementing
In scheme, rigid suspended component will then be mounted in the form of removable or is slidable to horizontal support elements, horizontally-supported structure
Part can be girder steel.By flexible connection, rigid suspended component can be between expanding position (heat) and punctured bit (cold) before level
After move, to compensate the expansion and contraction of flame retardant coating radial direction.
With reference to Fig. 5, the preferred embodiment of the present invention includes a bell 200.In use, the lower surface of bell 200, such as
Shown in Fig. 1, towards furnace chamber 30, it will the dust and other substances that packet last layer stove 10 generates.The thickness of this layer may 10 to
Between 20 centimetres, this depends on the heat flux radiated from slag surface and electric arc in various factors, including stove 10.Melt substance
Temperature can be differed from about 1500 to 2200 degrees Celsius, and the temperature of 200 lower surface of bell can from about 1200 degrees Celsius to
1600 degrees Celsius.Therefore, the bell 200 with low heat conductivity and low electric conductivity is suitable for stove 10 related to the present invention.
And one can repack the bell 200 that hull-skin temperature maintains 20 to 40 degrees Celsius into, particularly properly.By low conducting power
The relatively thick and solid bell 200 that material is made, can be suitably used for the reduction of surface temperature.
As shown, according to the example that the present invention is implemented, bell 200 can be made of multiple plates 210, plate
210 are shaped so that in the shape of bell 200 when being assembled together.In the embodiment shown in fig. 5, bosom plate 212 is removed
In addition, other plates are arc-shaped, and plate 210 is adjacent to connect into a series of ring, and central block 212 is then circle.Technology people
Member will be understood that, in the case of instructed without departing from the present invention, there are many other possible constructions are available.
As shown in Fig. 6 and Fig. 6 A, each plate 210 can be that the steel cap 215 of an opening is made, and use non magnetic gold
Category is made, such as copper, to prevent faradic generation.Technical staff will be understood that copper has the high fever for meeting desired use
Conductance, but the other materials that can also be used according to present inventive concept.In the embodiment depicted, a frame 220,
It is made of screw-thread steel, supporting steel cap 215 and network 230, network 230 can be a steel network.In spy
In other preferred embodiment, which can be made of high-temperature-resistant steel wire.
In preferred embodiments, steel cap 215 is filled using non-conductive castable 240, and castable 240 is passed with low-heat
The property led, such as high-alumina (Al2O3) castable.In general, thicker non-conductive and high mechanical strength material layer will provide
Better electric heating insulation.It is not susceptible to chemical reaction and castable not soluble in water, such as high alumina castable, is using process
The speed of middle degeneration is slower, has the longer service life, and use especially suitable for the bell 200 of stove 10 of the present invention.Generally
It is for first choice to carry out bell 200 using having the relatively thicker castable bed of material 240.In preferred embodiments, as shown in fig. 6,
The cast bed of material 240 can exceed steel cap 215 10 centimetres of depth, 15 centimetres or more, make its overall thickness reach 50 centimetres,
60 centimetres or thicker.In the preferred embodiment shown in, frame 220 and network 230 support cast bed of material 240 together
The increased quality of institute.In use, one layer of special object of cigarette ash, or can be referred to as " useless shell ", bell 200 can be accumulated in the following,
Additional thermal insulation is provided.
In the embodiment shown in fig. 5, each bell plate 210 is supported in longitudinal direction by multiple supporting members 235, support
Component 235 is then welded on frame 220, and extends through opening 250 appropriately sized on steel cap 215.The embodiment shown in
In, each plate 210 can be supported with four support members 235, and each support member is stretched out by a suitable hole 250.
In preferred embodiments, the suitable tar in any gap between adjacent plate 210, cement or similar
The material of function seals.Equally, in a further preferred embodiment, the gap between supporting member 235 and steel cap 215,
Gap namely in opening 250, is sealed with similar mode.
In preferred embodiments, bell 200 is configured and adapted to support and retain one layer of coolant liquid, such as water.It is excellent at these
In the embodiment of choosing, the upper surface of bell 200, which is shaped to, makes coolant liquid pour into or be sprayed onto on bell 200, can flow to stove
The outer edge of lid 200.In these preferred embodiments, as shown in FIG. 3, a slot 260 can be around the diameter of bell 200
It is made around bell 200 to outer edge, or by any point.The outer wall 275 of slot 260 makes than 270 higher of slot inner wall
One is retained in and reaches the flowing coating of cooling liquid of predetermined thickness on bell 200 and can be formed, it is dissipated for absorbing from stove 10
Heat.In preferred embodiments, slot 260 of the invention may include carrying the inner wall 270 and/or sensor that extend weir,
To monitor and/or control the height of coolant liquid.In a further preferred embodiment, coolant liquid can be filled with liquid displacement
It sets and is extracted out from slot 260 such as a pond pump, and can continuously be replaced with room temperature or frozen cooling fluid.The process of this displacement
It is round-the-clock so that flowing coating of cooling liquid ceaselessly updates and cooling, while floor height is maintained at predetermined altitude or preset range
Interior, floor height can correspond to furnace pressure to change, stove when in use furnace pressure usually 5 millimeters and 10 millimeters of water it
Between.In preferred embodiments, which can be between 20 millimeter to 50 millimeters.
In particularly preferred embodiments, the flowing coating of cooling liquid being retained on bell 200 can be water, can play sealing
Effect, to reduce the leakage from 10 inner space gas such as carbon monoxide of stove.In use, metallurgical furnace will produce
Noxious material, including gas.By retaining a flowing coating of cooling liquid such as water with predetermined thickness on bell 200, can lower
The gas flow and Dust Capacity that stove 10 is discharged to context operate so as to improve the safe present situation and reduction stove 10 of worker to ring
The influence in border.
It, when necessary can be in for example most although the opening for being used for feed pipe on bell 200 is not shown in Figure 5
On core block 212 or other places, are arranged some openings.These feed pipes are surrounded by a small-sized non-magnetic part, such as copper coin
Cylinder, which can be soldered on plate 215, to cooling feed pipe, and prevent coolant liquid with feed pipe to flowing down.Sealing
It can be used between feed pipe and copper coin cylinder.
In certain preferred aspects, can be placed between 260 outer wall 275 of slot and brick flame retardant coating 20 one it is close
Envelope component (not shown) seals to be formed, and further increases the seal degree to gas in stove 10, seal member can be a ring
Shape sealing element simultaneously has certain flexibility and elasticity.Such as the bad seals between adjacent plate 210, a small amount of coolant liquid is leaked from therebetween
Enter, and water is used as coolant liquid, aluminium oxide pouring material just shows its inertia and insoluble by the filler as plate 210
In the exemplary advantage of water.Further, since these liquid such as coolant liquids for leaking into, will be exposed among relatively high temperature, it can
Gasified.In the case where the integrality of bell 200 is destroyed, the sign of steam or coolant liquid vaporization can be used as and stop stove
Operation and the signal for replacing 200 faulty component of bell, such as, 210 failure of plate.
In certain embodiments, a bell 200 of the invention may include that a coating cools down to surround and prevent
Liquid is evaporated in ambient enviroment.
The bell 200 of the present invention can be suitble to that radially symmetrical metallurgical furnace 10 or cross section are pros with cross section
The metallurgical furnace of shape or rectangle is used together or installs.
With reference to Fig. 3 and Fig. 4, exemplary stove 10 can be cooled down by using air interchanger 500, and air interchanger can be
Fan, for extracting the air being wrapped in the air blanketing 505 of stove 10.Shown in the present embodiment, outer sleeve or strip of paper used for sealing
520, it can be formed from steel, surround stove 10, and containing there are one air blanketings 505.Outer sleeve 520 is divided into several sections
It falls, number can be corresponding with the number of shell paragraph 42, clips certain volume together with corresponding shell paragraph, needs
Into the air of line replacement.These sleeve paragraphs can be soldered on the wheel rim 43 of corresponding shell paragraph 42.Each paragraph
One air interchanger 500 can be set.In these embodiments, outer sleeve 520 shrinks and expands because of cold cycling in stove 10
When will be with the activity of shell paragraph 42.Air blanketing 505 can be made of multiple independent paragraphs, and each paragraph is clipped in shell section
Fall 42 and outer sleeve 520 paragraph among, will be heated by the outer surface of the shell 40 of stove 10 in stove use.It is painted in figure
Air interchanger 500 be connected to an air pipeline, and air pipeline is connected to a flexible position on 520 top of outer sleeve,
It will extract the hot gas in air blanketing 505 out.In the embodiment painted, gas displacement will be by by one or more wind
The method that fan generates suction is completed.
When the air in air blanketing 505 is extracted, negative pressure can be generated in sleeve 520.In preferred embodiments, empty
Pressure difference between air casing 505 and the external world is enough to be pumped into enough peripheral cold airs, to help box hat 40 to cool down, while can
To provide additional benefit, times that solidification skull liner and/or flame retardant coating 22,24,26 are leaked from interior furnace chamber 30 exactly will transmit through
What pernicious gas is taken away, although gas leaks out flame retardant coating 22,24,26 and can less occur.Such as the example of Fig. 4, in housing bucket
One or more air admission holes 510 on 520, shape can be slits, and room temperature or cold air enter sky in permissible environment
Air casing 505, to instead of discharge hot-air and make stove 10 cool down.According to some implementations of the present invention, and only with changing
Device of air or fan are compared, and the speed that air can be made to replace using the mode of outer sleeve 520 gets a promotion.In certain implementations
In scheme, if necessary, the air extracted out from air blanketing 505 can with filtering or handle in other ways, with removal or in
With pollutant therein.
In a further preferred embodiment, the system for cooling furnace 10 may include one or more nozzles 545,
Can be any suitable spraying device, for sprinkling coolant liquid in use to the outer surface 40 of stove 10.Especially excellent
In the embodiment of choosing, coolant liquid is melted into mist by one or more nozzles 545, is sprayed to the outer surface 40 of stove 10, nozzle
545 can correspondingly adjust in embedded thermocouple when detecting heat spot on flame retardant coating 20.Coolant liquid can be water,
It is heated in the outer surface of stove 10 40 and evaporates immediately, contribute to the cooling of shell 40.When the sprinkling system is taken a breath with described above
When device 500 is used in combination, the use of air interchanger 500 can be such that air is flowed along 10 outer surface 520 of stove, the coolant liquid of sprinkling
It can be evaporated with higher rate, to accelerate the cooling of shell 40.Coolant liquid rapid evaporation can also reduce the cooling of 10 lower end of stove
The accumulation of liquid, therefore relevant security risk can be reduced, such as since molten metal or other materials are leaked out from stove 10, make
It is leaked out at stove, so that the tiny probability event for touching any surplus liquid and exploding.
In preferred embodiments, detector (not shown) can be used to adjust the sprinkling of coolant liquid.In use,
When detecting that coolant liquid is accumulated on the rear surface of air blanketing 505, detector will reduce the sprinkling of coolant liquid, and/or
If at the same time still detecting with the presence of heat spot, increase air mass flow.Once waiting coolant liquids dispersion, evaporation or with other
Mode removes, and the coolant liquid on lower surface is restored to target level amount, such as without coolant liquid, and detector will increase coolant liquid
Spray amount, to prevent any overheat from occurring.If not detecting heat spot, liquid spray can not used.
With reference to Fig. 7 and Fig. 8, meet the preferred stove 10 of example various aspects of the present invention, including one or more electrodes 400, hangs
It hangs and is passed through furnace chamber 30 and the opening on bell 200.Opening on bell 200 can be located at neighbouring with bosom block 212
On plate 210.In an illustrated embodiment, electrode 400 is that the sealing system for being cooled to and being insulated by one is fixed on its position
It sets.In use, the voltage in stove 10 of the present invention on typical electrode 400 can be up to 1000 volts, and the variation of electric current will
Depending on rated power and electrode size.
Sealing system shown in Fig. 7 includes multiple pottery sealed insulation diaphragm seals 415 around electrode 400 and corresponds to
Radial compression sealing diaphragm seal 415 and electrode 400 extruding plate 410.Each ceramic seal gasket 415 can be done L-shaped,
To be supported on a shape for hat component 460, shape for hat component 460 can be with non-magnetic material such as copper, the system painted by Fig. 7
At.Extruding plate 410 can be made of non-magnetic material, such as copper.As shown in figure 8, each extruding plate 410 may is that by multiple
420 side pressure of side pressure component of spring is pressed on the ceramic seal gasket 415 and electrode 400.In discribed embodiment
In, each pair of diaphragm seal 415 and 410, which is shaped to, can be close to adjacent pair diaphragm seal 415 and 410, and its shape is closed
The annular ring around electrode 400 is collectively constituted suitablely.The ceramic seal chip part 415 and crush seal chip part 410 can be used
Make the cushion of the transverse movement of the primary seal, electrical insulator and a buffer electrode 400 of electrode 400.By side pressure component 420
The power of application must be adjusted so that the resistance of 400 longitudinal movement of electrode is prevented not reduce.
In the preferred case, each side pressure component 420 is supported by non magnetic stud 430, and stud can be made of copper and band
There is screw thread.Stud 430 can be soldered to or be otherwise connected to a relatively thicker nonmagnetic coldplate 475, can be with
It is made of copper.The pressure of the side pressure component 420, which can be used, to be adjusted with screw fashion by the screw 450 of stud 430.
Positioned at the top of extruding plate 410 and stud 430, it can be that nonmagnetic metal makes cap-shaped structure 460, can be arranged to by spiral shell
Column 430 supports.As shown in fig. 7, in particularly preferred embodiments, copper cap 460 can be screwed in 475 outer rim of the coldplate
The screw thread done, to form the sealing between cap 460 and copper cooling plate.
In certain preferred aspects, electrode seal is configured to cool down electrode 400 in use.Such as
Shown in Fig. 7, bottom that a non magnetic plate 475 that can be made of copper can be sealed as electrode.Ceramic seal gasket 415 can
475 bottom edge of coldplate is extended downward into, copper coin 475 is completely isolated in electrode 400.A thin layer ceramics cotton material 466 can be placed in
It between 415 and 410, can extend further downward, to fill up ceramic seal gasket 415, have between plate 475 and pourable material 405
Some or all of gap that may be present.Plate 475 is located on bell copper cap 215 and by its support, and cylinder cap 215 is then
It is supported by hanger bar 235.One layer of electrically insulating material 476 can be further placed between plate 475 and cylinder cap 215.
In preferred embodiments, the bottom surface of copper cooling plate 475 be covered with one layer can be high-alumina cast
Material, as electrical insulator.The insulating layer 405 thick can reach at least 50 to 100 millimeters.In order to fix the insulating layer 405, copper coin
475 bottom surface can be by digging the stria of 10 to 20 millimeters deeps come its coarse surface.In preferred embodiments, adjacent
Conductive network 220 in bell component and frame 230 will be by the aluminium oxide pouring material of at least 50 to 100 millimeters thicks
It is covered.In use, just in case 405 spalling failure of insulating layer castable, and flue dust can between electrode and copper coin 475
Electric bridge can be formed, insulating layer 476 can still exercise its function, and copper coin 475 and bell 215 are insulated.
A channel 480 can be defined in copper cooling plate 475, which guides coolant liquid circulation.The embodiment shown in
In, channel 480 is generally circular, but the skilled person will understand that, other shapes of cooling channel can also complete identical function.
In the embodiment shown in fig. 9, coolant liquid, such as water can introduce cooling channel 480 by flowing into component 482, then exist
It is flowed one week in cooling channel 480, and by flowing out the outflow cooling of component 484 channel 480.It can be in cooling channel 480
Coolant liquid pressurization, to improve cooling velocity.In particularly preferred embodiments, coolant liquid meeting in use
It is flowed along cooling channel 480, to cooling electrode 400, the cooling channel 480 of outflow, then cooling down is re-introduced into
Cooling channel 480, this is a continuously process.
As shown in fig. 7, an opening 465 can be done on non magnetic cap 460, it is used for compressed nitrogen (N2), Huo Zheqi
Its any suitable gas, such as argon gas, are filled into sealing element, to fill up ceramic seal gasket 415 in entire seal chamber and squeeze
Any gap that may exist between piece 410.
The ceramic seal gasket 415 can extend further up, to cover non magnetic cap 460 at the top of L-shaped.It is resistance to super
High temperature filler material 467 can be together filled in diaphragm seal 415 in the space to around electrode 400, can be played and be maintained reasonable gas
Pressure, limitation gas enter in stove and limitation gas leaks into the effect of ambient atmosphere.This seal chamber may include one it is non-magnetic
Property ring 462 is welded on cap structure 460.Make have screw thread for tightening nuts 464 in the top of ring 462.The nut and electrode
There are one wide arc gaps between 400.In preferred embodiments, ceramic washer 468 is placed on non magnetic spiral shell as electrical insulator
The lower section of cap 464 so that pressure is uniformly distributed on packing material 467, and packing material can serve as cushion pad and sealing.One
As for, electrode of the invention sealing will construct in such a way, with provide between all metals and electrode 400
Electrical isolation.In addition, in preferred embodiments, the material of all support electrode sealings can be by nonmagnetic metal or alloy
It constitutes, to reduce induced current generation.Copper is because its high-termal conductivity is the material recommended, to make including 410,460,462 Hes
Component including 462, these components can be contacted with copper cooling plate 475, and can therefore be cooled down in use.
In the metallurgical furnace for the ilmenite being used for according to an embodiment of the present invention, about the attached of brick and outer steel shell arrangement
Add example as follows:One metallurgical furnace with 5 to 60,000 kilowatts of operation powers, the flame retardant coating from skewback to headroom is by 2 layers of square magnesium
Stone brick (bricks of relatively thin 228.6 millimeters of bricks of thickness and 406.4 millimeters relatively thick of thickness) and 1 layer of graphite brick (228.6 millimeters thick)
Composition, by box hat round.The cellular inner surface of brick layer, together with the cavity generated by the different brick of the bond thickness that interlocks, all
It is covered with one layer of (50.8 millimeters) MgO castable, expendable material when being used as starting.However for being in molten iron region brick
Hollow cavity, if filling castable can be used as a kind of option.Box hat internal diameter is (under heat condition) under normal stove operational circumstances
13,379 millimeters.When completely cooling in stove, it is expected that 13,208 millimeters will be contracted to, and it is 85 millimeters radial to reflect flame retardant coating
Contraction.It is assumed that shell is constituted with 8 arc-shaped steel shell plates, and it is placed between radial brick layer with approximation using expansion paper
Expanded configuration, about 67 millimeters of the gap estimation before stove starts between each plate.For the innermost layer of periclase brick layer, inner width
Degree is 101.6 millimeters (most hot sides), and each two brick needs the expansion paper of 7 thickness 0.4mm.In the outer layer of periclase brick layer, then
Two expansion paper are needed per brick.For graphite brick, it is proposed that use graphite felt as cushion.It is assumed that in new installation, it is conventional to operate
Graphite felt under state, which can be pressurized, reduces the 20% of its thickness, and when being contracted to complete cooling, it reduces it because of compression
The 70% of thickness.Therefore, it is estimated that, each two graphite brick need 1 not by being the graphite felt of 8 millimeters thicks when any compression.
Under heat condition, thickness is 6.4 millimeters, and when bearing maximum compression, its thickness becomes 2.4 millimeters.
In the additional examples, expansion paper can also be used in cupola well flame retardant coating.It is estimated that innermost layer each brick week
Enclosing can need to place 5 expansion paper.6 expansion paper can be needed under the layer, on next layer (second layer).For
Next layer (second layer) of flame retardant coating, every 3 brick can need 8 expansions as a plate, and in the layer and next layer (the
Three layers) between can place two expansion paper.Expansion paper can not be had between the third layer and graphite brick of flame retardant coating.It is resistance at this
Fire bed top layer, the sacrificial layer that thick 50.8 millimeters of MgO castables are made, casts in again on this layer of top surface.
, when in use can be movable during expansion and contraction in view of flame retardant coating in the additional examples, stove starts preceding every
Respectively weld a wheel rim in the both ends of the vertical coverboard of a arc.Adjacent segmentation paragraph can on carriage bolt be fixed to bottom
On the wheel rim of cupola well, and fixed on the steel floor of top.On cupola well it is brick it is good after, shell plates can be installed, spiral shell is used
Nail, bolt or other suitable fixed forms, are such as connected to lock body plate on wheel rim 46.Then it is close to housing segments
Bond brick layer 26, remaining layer 24,22 then 26 bond of brick layer form flame retardant coating.It is laid with completion in brick and around the bullet of coverboard
Spring is after installation is complete, and the fixing device can then be shed, to allow steel plate paragraph can be with stove expansion or shrinkage freely
Activity.It is estimated that the temperature in the most hot face of internal layer brick is about 800 to 900 degrees Celsius in operation, and the same brick
Colder side is about 400 degrees Celsius.For total high 11 meters of stove, hotter side by expansion increase 152mm and as a comparison
Cold side, which then expands, increases about 84 millimeters.Therefore, the height that brick can be corrected, to allow this non-uniform expansion, otherwise
Top block may tilt, and the spring pressure born on brick will be uneven.For example, for design it is a height of 4 inches or
101.6 millimeters of brick, every 4th layer of brick, the hotter side of brick can 2.5 millimeters of length, every 68 millimeters, it is necessary to correct.Brick
Total number of plies is 108, can not be modified to 8 layers of top brick.For close to the lower brick layer of shell, similar correction can be done, but
3 millimeters of amendments only are made to every layer 5 brick.Graphite brick can not be corrected, because its temperature is low and linear expansion coefficient is several
It is zero.At the top of abutment wall brick layer, it can be laid with one layer of Teflon TM, be then laid with steel plate at the top of it, for directly engaging
It can be the vertical compression component of spring.
Its object is to for example, and not lying in present invention is limited only to disclosed implementations for the description of this invention
Case.To many modifications and changes that the present embodiment carries out, it is for those those skilled in the art in the art
It will be apparent.It is and to make other this technologies to explain the principle of the present invention and its practical application to select the present embodiment
The those skilled in the art in field are it will be appreciated that the present invention, by various modifications to realize different embodiments so that it can be applicable in
In the purposes of other imaginations.
Claims (18)
1. one for the electrode sealing in metallurgical furnace, towards metallurgical furnace include a furnace chamber, and by being stretched from an opening
Enter to electrode therein and heated, it is characterised in that the electrode, which seals, includes:
At least three groups of diaphragm seals, connect from side two-by-two, and each diaphragm seal is ined succession a side pressure component, for making diaphragm seal
Surface presses to electrode, to allow electrode longitudinally-moving in electrode seals, while can be electrically insulated between electrode and opening.
2. electrode sealing according to claim 1, it is characterised in that at least three groups of diaphragm seals carry for surrounding them
For some gaps, to allow the electrode in the freely activity of laterally energy.
3. electrode sealing according to claim 1, it is characterised in that at least three groups of diaphragm seals will allow electrode to exist
Wherein make lateral movement, while still sealing gas.
4. electrode sealing as claimed in any of claims 1 to 3, it is characterised in that at least three groups of diaphragm seals
Include two layers, internal layer is ceramic seal gasket, and outer layer is then copper diaphragm seal, a circle of this two layers of diaphragm seal composition, and
The internal diameter of ceramic seal gasket will be bigger than the internal diameter of electrode, to provide some gaps.
5. electrode sealing as claimed in any of claims 1 to 4, it is characterised in that the side pressure component is one
Spring.
6. electrode sealing as claimed in any of claims 1 to 5, it is characterised in that the side pressure component can be adjusted
Section, makes it apply greater or lesser lateral pressure, one end of side pressure component presses against copper diaphragm seal, and the other end is then adjusted
Copper screw.
7. electrode sealing as claimed in any of claims 1 to 6, it is characterised in that the side pressure component is can to replace
It changes.
8. electrode as claimed in any of claims 1 to 7 sealing, it is characterised in that side pressure component be electrical isolation
, side pressure component and copper diaphragm seal junction and with all employ plastic washer at copper screw connection.
9. electrode sealing as claimed in any of claims 1 to 8, it is characterised in that the electrode sealing is further wrapped
Included be filled at least three groups of electrode diaphragm seals, the electrically insulating material of surrounding them, play the insulation material of air seal
Material is pressed against and is fixed by a threaded copper cap, which is tightened on a screw thread copper ring, and screw thread copper ring is then welded on it
On another lower copper cap, it is thusly-formed a cavity and surrounds diaphragm seal.
10. electrode sealing according to claim 9, it is characterised in that the electrically insulating material is pyroceram fibre material
Material.
11. electrode sealing as claimed in any of claims 1 to 10, it is characterised in that further comprise an electricity
Insulate cooling element, surrounds electrode.
12. electrode sealing according to claim 11, it is characterised in that the cooling element includes a casting in bronze plate.
13. electrode sealing according to claim 12, it is characterised in that there are one protective layer, the guarantors under the casting in bronze board bottom
The material of sheath is durable insulating materials.
14. electrode sealing according to claim 12, it is characterised in that the insulating materials is pourable material.
15. electrode sealing according to claim 14, it is characterised in that the mould material is high alumina castable.
16. the electrode sealing according to any one of claim 1 to 15, it is characterised in that the casting in bronze plate defines one
The inside groove of item one guides cooling liquid to circulate wherein.
17. the electrode sealing according to any one of claim 11 to 16, it is characterised in that the cooling element includes
One copper coin.
18. the electrode sealing according to any one of claim 11 to 16, it is characterised in that the boundary face of the cavity
It is at least part of to belong to cooling element.
Priority Applications (1)
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CN201810283685.3A CN108592640B (en) | 2013-12-20 | 2013-12-20 | Electrode seal for metallurgical furnace |
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CN201380078042.0A CN105579803B (en) | 2013-12-20 | 2013-12-20 | metallurgical furnace |
PCT/CA2013/001086 WO2015089622A1 (en) | 2013-12-20 | 2013-12-20 | Metallurgical furnace |
CN201810283685.3A CN108592640B (en) | 2013-12-20 | 2013-12-20 | Electrode seal for metallurgical furnace |
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CN201380078042.0A Division CN105579803B (en) | 2013-12-20 | 2013-12-20 | metallurgical furnace |
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CN201810283685.3A Active CN108592640B (en) | 2013-12-20 | 2013-12-20 | Electrode seal for metallurgical furnace |
CN201810283706.1A Active CN108613555B (en) | 2013-12-20 | 2013-12-20 | Metallurgical furnace for smelting minerals and method for retrofitting an existing refractory layer |
CN201810282722.9A Active CN108826959B (en) | 2013-12-20 | 2013-12-20 | Metallurgical furnace and method for retrofitting a metallurgical furnace |
CN201810283155.9A Active CN108613554B (en) | 2013-12-20 | 2013-12-20 | Furnace cover for metallurgical furnace |
CN201380078042.0A Active CN105579803B (en) | 2013-12-20 | 2013-12-20 | metallurgical furnace |
CN201410803981.3A Active CN104729299B8 (en) | 2013-12-20 | 2014-12-19 | Metallurgical furnace |
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CN201810283706.1A Active CN108613555B (en) | 2013-12-20 | 2013-12-20 | Metallurgical furnace for smelting minerals and method for retrofitting an existing refractory layer |
CN201810282722.9A Active CN108826959B (en) | 2013-12-20 | 2013-12-20 | Metallurgical furnace and method for retrofitting a metallurgical furnace |
CN201810283155.9A Active CN108613554B (en) | 2013-12-20 | 2013-12-20 | Furnace cover for metallurgical furnace |
CN201380078042.0A Active CN105579803B (en) | 2013-12-20 | 2013-12-20 | metallurgical furnace |
CN201410803981.3A Active CN104729299B8 (en) | 2013-12-20 | 2014-12-19 | Metallurgical furnace |
Country Status (13)
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US (4) | US9752830B2 (en) |
CN (6) | CN108592640B (en) |
AP (1) | AP2016009317A0 (en) |
AU (1) | AU2013408178B2 (en) |
BR (1) | BR112016013581B1 (en) |
CA (2) | CA2932161C (en) |
CL (1) | CL2016001493A1 (en) |
FI (2) | FI20195097A1 (en) |
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CN112902674B (en) * | 2021-01-26 | 2024-04-30 | 中冶赛迪工程技术股份有限公司 | Air-cooled contact pin type bottom electrode |
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